Wavelength sensing lighting system and associated methods for national security application

ABSTRACT

A wavelength sensing lighting system may include a light source, a sensor and a controller. One or more light sources and sensors may be included in an array. The light source may emit an illuminating light and the sensor may sense an environmental light. The illuminating light may include data light. The lighting system may include a plurality of nodes connected in a network. The nodes may communicate by emitting and receiving the data light, which may be analyzed by the controller. The light source and the sensor may be provided by a light emitting semiconductor device that is capable of emitting illuminating light and receiving environmental light. A conversion material may convert the wavelength of a source light into a converted light. The conversion material may increase the wavelength range of light emittable and detectable by the lighting system.

RELATED APPLICATIONS

This application is filed in relation to U.S. patent application Ser. No. 13/269,222 titled “WAVELENGTH SENSING LIGHTING SYSTEM AND ASSOCIATED METHODS” filed by the inventor of the present application on Oct. 7, 2011, the entire contents of which are incorporated herein by reference.

FIELD OF THE INVENTION

The present invention relates to the field of lighting systems and, more specifically, to lighting systems that can emit and sense light within a wavelength range, and associated methods.

BACKGROUND OF THE INVENTION

Lighting systems have been used to illuminate spaces since the discovery of fire. Over the years, technology has brought us the incandescent light, which produces light by heating a metal filament, causing it to radiate heat. Although the incandescent light is capable of illuminating an area, it does so with little efficiency.

The fluorescent lamp was introduced to provide comparable light while using less energy. The fluorescent lamp excites a gas, such as mercury vapor, within a confined volume. The atoms of the excited gas typically produce ultraviolet light as it moves between energy levels. The ultraviolet light is then absorbed by a conversion material, such as a phosphor. The phosphor may shift the wavelength range of the absorbed light, emitting a light with longer wavelengths. This shift may be known to skilled artisans as a Stokes shift. This phosphor-emitted or converted light may be within the visible spectrum, which may be used to illuminate a space.

Seeking additional efficiency, continuing advancements in technology have brought the light emitting semiconductor device, and more specifically, the light emitting diode. Light emitting diodes may emit light when driven by an electrical current. Like fluorescent lights, conversion materials may be applied to a light emitting semiconductor device to alter the wavelength range of the light used to illuminate a space.

Lighting systems that include a conversion material may conveniently allow the conversion of a source light emitted from a light source into light of a different wavelength range. Often, such a conversion may be performed by using a luminescent, fluorescent, or phosphorescent material. The wavelength conversion materials may sometimes be included in the bulk of another material, applied to a lens or optic, or otherwise located in line with the light emitted from light source. In some instances the conversion material may be applied to the light source itself. A number of disclosed inventions exist that describe lighting devices that utilize a conversion material applied to an LED to convert light with a source wavelength range into light with a converted wavelength range.

Additional strategies to reduce power consumption involve controlling a lighting system to illuminate a space only when the illumination is required. Traditionally, toggle switches have been included in lighting circuits to allow a user to directly control the operational state of the light. Additionally, timers maybe be included in the light circuit to turn a light on and off according to a predetermined or dynamic timing schedule. However, switches and timers offer little flexibility unless directly engaged by a user.

Sensors may additionally be included in lighting systems to control operation upon the sensed compliance with a desired event. As an example, sensors may determine the level of light in a space, which may, in turn, cause a lighting system to be turned on upon sensing that a value falls below a threshold value. As an additional example, sensors may detect the presence of movement in a space to control illumination. However, including dedicated sensors may increase the number of parts and complexity required to build the lighting system, thereby increasing its manufacturing cost.

Additionally, each lighting device may operate independent of other lighting devices, requiring sensors included in each lighting device, further increasing production costs. Some proposed solutions have included wireless radio transmitters in the lighting systems, to allow communication between the devices included therein. However, the inclusion of wireless radios further increases the complexity and number of components included in the lighting system.

One proposed solution is described in by international patent application publications WO 2011/016860, WO 2011/008251, WO 2010/098811, and WO 2010/027459, each by Knapp, and that each involve using the light emitting semiconductor device to perform the operations of a photodiode during portions of the duty cycle when the light emitting semiconductor device is not emitting light. The aforementioned Knapp applications additionally recite using the light emitting semiconductor devices to transmit and receive bi-directional communication between devices included in the lighting system. However, the Knapp applications employ data transmission methods that may result in redundant data transmission, decreasing the effective throughput of the system. Additionally, the Knapp applications lack advanced wavelength sensing functionality, limiting the effectiveness of the system disclosed therein.

There exists a need for a wavelength lighting system that can emit an illuminating light and sense an environmental light by altering its operational state between various portions of the duty cycle. There further exists a need for a lighting system that can analyze the sensed environmental light to alter the characteristics of the nodes included in the lighting system. There exists a need for a lighting system that includes a wavelength conversion material to expand the wavelength range of light that may be emitted or detected by a light emitting semiconductor device. Additionally, there exists a need for a lighting system wherein the nodes intercommunicate to increase the effectiveness of the system.

SUMMARY OF THE INVENTION

With the foregoing in mind, embodiments of the present invention are related to a wavelength sensing lighting system that can emit illuminating light and sense environmental light during portions of the duty cycle. Additionally, according to an embodiment of the present invention, the lighting system may advantageously analyze the sensed environmental light to alter the characteristics of nodes included in the lighting system. A wavelength conversion material may be included to expand the wavelength range of light that may be emitted or detected by a light emitting semiconductor device. The lighting system may include nodes that may advantageously intercommunicate with one another to increase the effectiveness of the system. The sensed environmental light may be analyzed by the lighting system to determine one or more condition of the environment.

With the foregoing in mind, the present invention provides a lighting system comprising a sensor and a controller, and according to at least one embodiment, a light source. The light source may be included in an array to emit illuminating light. The sensor may additionally be included in the array to sense environmental light from an environment. The controller may be operatively connected to the sensor to analyze the environmental light that is sensed. The controller may also be operatively connected to the light source to control emitting the illuminating light.

The controller may analyze the environmental light to detect or generate data relating to a condition of the environment. The data may be transmittable in data light, which may be defined by at least one data wavelength. One or more data wavelength may be defined relative to the illuminating light.

The data may be transmittable by the light source included in the array. The sensor may selectively sense a dominant wavelength in the environmental light that is defined by the controller. Moreover, the sensor may selectively sense a plurality of dominant wavelengths in the environmental light. At least a part of the plurality of dominant wavelengths may be concatenated to define the data relating to the condition in the environment.

The controller may receive the data using the sensor, which it may analyze. The controller may also control transmitting the data light from the light source. The light source and/or the sensor may be selectively operable, wherein the illuminating light may be selectively emitted from the light source in a plurality of directions and the environmental light may be received by the sensor from the plurality of directions.

According to an embodiment of the present invention, the data relating to the condition in the environment may include an image. The image may be included in a series of images, which may be concatenated to create a video. Additionally, the data includes a plurality of images that may be compared to determine a proximate variance of an object among the plurality of images. The proximate variance may be analyzed by the controller to determine movement of the object. Additionally, the movement may be analyzed by the controller to determine velocity of the movement.

According to an embodiment of the present invention, the array may include a plurality of sensors. Each sensor included in the plurality of sensors may be sensitive to at least one wavelength respective to the each sensor. Each sensor may be selectively operable.

According to an embodiment of the present invention, the light source and the sensor may be included as a light emitting semiconductor device. The light emitting semiconductor device may be selectively operable between a sensing operation and an emitting operation. The sensing operation may be defined by the light emitting semiconductor device sensing the environmental light. The emitting operation may be defined by the light emitting semiconductor device emitting the illuminating light. The array may include a plurality of light emitting semiconductor devices.

According to an embodiment of the present invention, the controller may designate at least a part of the illuminating light as a marker light. The controller may control the light source to emit the illuminating light including the marker light to the environment. The illuminating light may be reflected from a point of reflection in the environment as the environmental light. The environmental light may continue to include the marker light. The sensor may sense the environmental light including the marker light, from which the controller may calculate a delay between emitting the marker light and sensing the marker light. The controller may also analyze the delay to determine a distance between the array and the point of reflection.

According to an embodiment of the present invention, the lighting system may comprise a network of nodes. Each of the nodes in the network of nodes may include a light source, the sensor, and the controller. Each node in the network of nodes is proximately aware of an additional node in the network. Delay may be analyzed by a node in the network to determine the distance between the node and the point of reflection. That distance may be intercommunicated within the network by transmitting and receiving the data light. Additionally, the condition in the environment may be determined by analyzing the distance calculated by at least a portion of the nodes in the network. Furthermore, the controller may analyze the distance calculated by at least a portion of the nodes in the network to determine a multidimensional arrangement of the condition in the environment. The nodes may intercommunicate by transmitting and receiving an electromagnetic signal.

According to an embodiment of the present invention, the dominant wavelength may be indicative of a substance present in the environment. Also, according to an embodiment of the present invention, the controller may control the array to emit an alert upon sensing an event.

According to an embodiment of the present invention, the lighting system may further comprise a switching circuit to alternate the light emitting semiconductor device between the sensing operation and the emitting operation. The light emitting semiconductor device may emit the illuminating light and receive the environmental light substantially simultaneously. Also, the light emitting semiconductor device may include a light emitting diode to emit the illuminating light and a photodiode to sense the environmental light. The light emitting diode may be operable as the photodiode.

According to an embodiment of the present invention, the controller may analyze the environmental light by measuring a drive voltage of the light emitting semiconductor device, determining a difference between a measured voltage across the light emitting semiconductor device and the drive voltage, and performing time-domain matching of the measured voltage and the environmental light using cross-correlation.

According to an embodiment of the present invention, the array may include a plurality of light sources. At least a portion of the light sources included in the array may be monochromatic light emitting diodes (LED), white light emitting diodes (LED), and/or infrared light (IR) emitting diodes (LED). Additional types of light emitting semiconductor devices may be included. According to an additional embodiment of the present invention, at least a part of the illuminating light may selectively include a biological affective wavelength to affect an object in the environment.

According to an embodiment of the present invention, at least a portion of the nodes in the network may perform an analysis using distributed computing. Additionally, at least a portion of the nodes in the network may synchronize by including a synchronization signal in an electromagnetic signal.

According to an embodiment of the present invention, the data light may be defined by a plurality of data wavelengths. The data may be transmittable at the plurality of data wavelengths. A quantity of data wavelengths included in the data light may correlate with a bandwidth at which the data is transmittable. The data light may also include at least one addressing bit to address the nodes intended to receive the data. Furthermore, the data included in the data light may include at least one error detection bit.

According to an embodiment of the present invention, feedback regarding an analysis performed by the controller may be stored in memory. The feedback from the analysis may be intercommunicated within the network. The feedback may be analyzed using machine learning. The feedback may also be analyzed using a neural network. The controller may receive the feedback regarding the prior analysis from the memory and analyze the feedback regarding the prior analysis to perform a subsequent analysis. This subsequent analysis may also be performed using machine learning.

According to an embodiment of the present invention, the lighting system may further comprise a wavelength conversion material between the array and the environment. The conversion material may absorb at least part of a source light and emit a converted light having a converted wavelength range. The source light may be received and absorbed by the wavelength conversion material. The converted light may be emitted by the wavelength conversion material. The wavelength conversion material may include a fluorescent material, a luminescent material, and/or a phosphorescent material.

The converted wavelength range of the converted light may include a variable dominant wavelength respective to the condition in the environment. The dominant wavelength may be indicative of a substance in the environment. The controller may correlate the dominant wavelength with the substance. The substance be an object, element, compound, particulate, or biological agent.

The illuminating light may be received by the wavelength conversion material as the source light, which may be emitted by the wavelength conversion material as converted light within the converted wavelength range. Alternatively, the environmental light may be received by the wavelength conversion material as the source light, which may be emitted by the wavelength conversion material as converted light to be received by the sensor as converted light within the converted wavelength range. The converted wavelength range may include shorter wavelengths than the source wavelength range resulting from performing an anti-Stokes shift. Alternatively, the converted wavelength range may include longer wavelengths than the source wavelength range resulting from performing a Stokes shift.

According to an embodiment of the present invention, the controller may be operatively connected to a voltage sensor to sense an open circuit voltage across the sensor.

According to an embodiment of the present invention, the data light may transmit the data using an operation including pulse width modulation (PWM), pulse amplitude modulation (PAM), intensity modulation, color sequencing, and/or duty cycle variation. A sample rate at which the data is transmitted in the data light may be dynamically adjustable by the controller. An increased sample rate may correlate with an increased resolution sensed by the array.

Data may be included in the data light digitally. The data included in the data light may also be encrypted. The light source may be operable in a pulsed mode. The controller may characterize a luminosity of the environmental light. The controller may also process the environmental light to remove noise.

According to an embodiment of the present invention, the array may include a piezoelectric substrate. According to additional embodiment of the present invention, the lighting system may further comprise a power supply to drive the array.

A method aspect of the present invention may include analyzing the environmental light to detect or generate data relating to a condition of the environment. The data may be transmittable in data light by the light source included in the array. The data light may also be defined by at least one data wavelength, wherein one or more data wavelength is defined relative to the illuminating light. The method aspect may additionally include selectively sensing a plurality of dominant wavelengths in the environmental light, which may be defined by the controller.

The plurality of dominant wavelengths may be concatenated to define the data relating to the condition in the environment. The controller may be used receive the data using the sensor from a plurality of directions, analyze the data, and transmit the data light from the light source in a plurality of directions.

The light source and the sensor may be selectively operated.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1-30 are included and described in U.S. patent application Ser. No. 13/269,222, the entire contents of which are incorporated herein by reference. The description of the drawings in the '222 Application should be read as being included herein.

FIG. 31 is a diagram indicating the relative luminosity of light emitted by an infrared LED, according to an embodiment of the present invention.

FIG. 32 is a diagram indicating the relative luminosity of light detectable by an infrared LED, according to an embodiment of the present invention.

FIG. 33 is a diagram indicating the relative luminosity of light emitted by a blue LED, according to an embodiment of the present invention.

FIG. 34 is a diagram indicating the relative luminosity of light detectable by a blue LED, according to an embodiment of the present invention.

FIG. 35 is a diagram indicating the relative luminosity of light emitted by a blue LED, which includes light converted by a wavelength conversion material, according to an embodiment of the present invention.

FIG. 36 is a diagram indicating the relative luminosity of light detectable by a blue LED, which includes light converted by a wavelength conversion material, according to an embodiment of the present invention.

FIG. 37 is a diagram indicating the relative luminosity of light to be detected in an example, according to an embodiment of the present invention.

FIG. 38 is a diagram indicating the relative luminosity of light by a detected in an example, which has been converted by a wavelength conversion material, according to an embodiment of the present invention.

FIG. 39 is a block diagram of detecting an object in an environment, according to an embodiment of the present invention.

FIG. 40 is a flowchart illustrating the operation of FIG. 39, according to an embodiment of the present invention.

FIG. 41 is a time line relating to the events of the flowchart of FIG. 39, according to an embodiment of the present invention.

FIG. 42 is a block diagram of an array of light emitting semiconductor devices to communicate data light using multiple channels, according to an embodiment of the present invention.

FIG. 43 is a diagram indicating the relative luminosity of the channels generated by the array of FIG. 42.

FIG. 44 is a block diagram of detecting a substance in the environment, according to an embodiment of the present invention.

FIGS. 45A, C, and E are diagrams indicating the relative luminosity of the channels generated by the array of FIG. 44.

FIG. 46 is a block diagram of detecting a substance in the environment using a wavelength conversion material, according to an embodiment of the present invention.

FIGS. 47A-E are diagrams indicating the relative luminosity of the channels generated by the array of FIG. 46.

FIGS. 48-51 are schematic diagrams showing a correlation of data sensed in a data light using the lighting system according to an embodiment of the present invention to an image.

FIG. 52 is a diagram of an image created from sensed environmental light, according to an embodiment of the present invention.

FIG. 53 is a diagram of an image created from sensed environmental light, according to an embodiment of the present invention.

FIG. 54 is a diagram of an image created from sensed environmental light, according to an embodiment of the present invention.

FIG. 55 is a top plan view of an array of nodes located along a roadway, according to an embodiment of the present invention.

FIG. 56 is a front perspective view of an object sensed on the roadway illustrated in FIG. 55, according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

The present invention will now be described more fully hereinafter with reference to the accompanying drawings, in which preferred embodiments of the invention are shown. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. Those of ordinary skill in the art realize that the following descriptions of the embodiments of the present invention are illustrative and are not intended to be limiting in any way. Other embodiments of the present invention will readily suggest themselves to such skilled persons having the benefit of this disclosure. Like numbers refer to like elements throughout.

In this detailed description of embodiments of the present invention, a person skilled in the art should note that directional terms, such as “above,” “below,” “upper,” “lower,” and other like terms are used for the convenience of the reader in reference to the drawings. Also, a person skilled in the art should notice this description may contain other terminology to convey position, orientation, and direction without departing from the principles of the embodiments of the present invention.

This application is related to U.S. patent application Ser. No. 13/269,222 filed on Oct. 7, 2011, titled “WAVELENGTH SENSING LIGHTING SYSTEM AND ASSOCIATED METHODS,” the inventors of which include the inventors of the present application. The entire contents of the Ser. No. 13/269,222 application is hereby incorporated by reference. The information incorporated is to be considered as much a part of the present disclosure as if the text was repeated in the application, and should be treated as part of the text of the present disclosure. Accordingly, although FIGS. 1-30 are referenced in this application, no further discussion regarding these drawings and the patent reference numbers illustrated therein, are necessary.

Referring now additionally to FIGS. 31-56, a wavelength sensing lighting system 10, according to an embodiment of the present invention, is now described in greater detail. Throughout this disclosure, the wavelength sensing lighting system 10 may also be referred to as a lighting system 10, system, device, embodiment, or the invention. Alternate references to the wavelength sensing lighting system 10 in this disclosure are not meant to be limiting in any way. A person of skill in the art, after having the benefit of this disclosure, will appreciate that the present invention may include embodiments that perform total, partial, and minimal conversion of a source light 42 into a converted light 46. Additionally, skilled artisans will appreciate that, in embodiments with partial wavelength conversions, the remaining, unconverted source light 42 may be combined with the converted light 46 to be directed in the desired output direction, for example, to illuminate a space or to sense a condition in the environment.

Additionally, in the following disclosure, a light source is disclosed as a component of the lighting system 10, according to an embodiment of the present invention. The light source may be a light emitting semiconductor device 40, which may be referenced throughout the following disclosure. Additionally, a sensor may be discussed to sense environmental light 48. The sensor may be a light source, such as light emitting semiconductor device 40. The light emitting semiconductor device 40 may include, among other devices, a light emitting diode (LED). In embodiments of the present invention, the operation of the sensor may be performed by a light source, such as a light emitting semiconductor device 40. As a result, the light emitting semiconductor device 40 should be assumed to collectively include the light source and the sensor in at least one embodiment of the present invention.

Furthermore, in the following disclosure, a controller 61 may be discussed to analyze the environmental light 48 sensed by the sensor and control the emission of illuminating light 44 by the light source. The sensor and the light source may be a light emitting semiconductor device 40. The controller may collectively include an analysis processor to analyze sensed environmental light 48 and a lighting controller 61 to control emitting illuminating light 44.

The controller 61 may be a computerized device capable of sending, receiving, and analyzing data and electronic signals. The controller 61 may control one or more light source, which may be included in an array 39. However, the functionality of the controller 61 should not be limited to light source controlling operations. The controller 61 may additionally accept and analyze data or electronic signals received from one or more sensor. The controller 61 may perform the operations of both an analysis processor and a lighting controller 61, among numerous other operations that would be apparent to those skilled in the art. Skilled artisans will additionally appreciate that the controller 61 may be described broadly herein as a computerized device to perform computational operations, including processing data.

Skilled artisans will appreciate additional embodiments of a light source, for example, and without limitation, electroluminescent, laser, incandescent, and fluorescent light sources. Although the light source may be discussed in regard to a specific embodiment of a light emitting semiconductor device 40, a person of skill in the art will appreciate that additional light sources may be included with the operation of the various embodiments of the present invention, are intended to be included within the scope of the same. As a result, skilled artisans should not view the use of a light emitting semiconductor device 40 through this disclosure as limiting the scope of the light source.

As previously discussed in the disclosure incorporated herein, a light emitting semiconductor device 40 may be used as a lighting device and/or sensor, which may emit illuminating light 44 and/or detect environmental light 48 from a plurality of directions. More specifically, and without limitation, an LED may be operable as a photodiode in replacement or addition to being a light emitter. LEDs are also capable of detecting incident light and producing an output voltage dependant on the intensity and the wavelength of such incident light. The lighting system 10, according to an embodiment of the present invention, may advantageously be implemented using an LED as a source of light emission and device for light detection, advantageously decreasing the complexity and manufacturing cost of the system 10.

The efficiency of a light emitting semiconductor device 40, such as an LED, operating as a light detecting sensor may not be as good as that achieved by a dedicated sensor, such as a photodiode or a phototransistor. However, light emitting semiconductor devices 40 can provide enough sensitivity to allow their use as photodetectors for a plurality of applications consistent with the scope of the present invention. Typically, if an LED is inserted into an electronic circuit that may normally accept a dedicated photodiode sensor, the LED may perform significantly the same operation as the dedicated photodiode. The LED may be switched between an emitting circuit, detecting circuit, and any other circuit, as it has been contemplated in accordance with an embodiment of the present invention. The LED, much like a typical photodiode, may be sensitive to a wavelength range that is equal or lesser than the light that would be emitted by the LED. In other words, an LED operating as a sensor may typically detect light comprised of wavelengths equal to and shorter than the wavelengths that could be emitted by the LED.

In one embodiment, sequential and temporally correlated PWM of individual LEDs of an array 39 may be operated in conjunction with temporally correlated sensing function to sense one or more condition of an environment. For example, in one embodiment, a single LED may be powered to emit illuminating light. Additional LEDs in the array 39 may be used for detection of environmental light 48 (e.g., during one or more duty cycles). In another embodiment, scanning along particular geometries of the array 39 can be used to resolve environmental signals, e.g., scanning along the vertical, horizontal, or diagonals of a rectangular or otherwise shaped array 39. Alternatively or additionally, multi-color detection of environmental light 48, including the use of metameric whites, can be used for greater resolution. Signal processing of the sensed data correlated with the illuminating light 44 is used to characterize the environment. Mathematical analysis and signal processing techniques including Fourier transforms may be used to analyze the data.

In another embodiment, optics may be applied to one or more light emitting semiconductor devices 40, or portions of light emitting semiconductor devices 40 included in the array 39 or across the network 69, to improve the resolution at which a condition of the environment is detected. The resolution may be improved by allowing one or more light emitting semiconductor device 40 to detect different regions of an illuminated space. For example, LEDs may illuminate and/or detect multiple directions substantially simultaneously.

Provided without the intent to limit the present invention, some examples of an LED, an illustrative type of light emitting semiconductor device 40, operating as a sensor will now be discussed. In a first example, an infrared LED may be included in a circuit as a photodiode. The infrared LED may emit illuminating light 44 with an approximate wavelength of 1400 nanometers. This may result in the infrared LED being usable as a photodetector to detect infrared light with wavelengths shorter than 1400 nanometers, visible light, and ultraviolet light. However, the illuminating light 44 emitted by the infrared LED may not be detected by a human without first being converted into visible light.

As another example, a blue LED may be included in a circuit as a photodiode. The blue LED may emit illuminating light 44 with an approximate wavelength of 460 nanometers. This illuminating light 44 may include high efficacy light which would be visible to humans. However, the blue LED may only be capable of detecting environmental light 48 with wavelengths shorter than 460 nanometers, which may include additional blue light and ultraviolet light, without performing some wavelength conversion operation on the environmental light 48 prior to detection.

A person of skill in the art will appreciate that one or more LEDs may be included in the array 39 to emit illuminating light 44 within an acceptable wavelength range, and detect environmental light 48 within an acceptable wavelength range. For example, an array 39 may include a plurality of blue LEDs and a plurality of infrared LEDs. The blue LEDs may emit an illuminating light 44 that may be detectable to humans. Additionally, the infrared LEDs may detect an environmental light 48 within the visible spectrum. In this example, infrared LEDs would be able to detect at least part of the light emitted by the blue LEDs.

In another example, one or more wavelength conversion material 30 may be located between the LED and the environment to convert the wavelength range of light. The wavelength conversion material 30 may perform a Stokes shift, wherein the conversion material 30 may absorb one or more photon, an elementary particle of light, from a source light 42. The absorbed photon may cause the conversion material 30 to enter an excited state. The conversion material 30 may then emit a photon, allowing the conversion material 30 to relax from the excited state as it emits converted light 46. The photon of the converted light emitted by the conversion material 30 during a Stokes shift may have less energy than the absorbed source light photon.

Another type of wavelength conversion material 30 may perform an anti-Stokes shift, wherein the conversion material 30 may emit a converted light 46 with higher energy, and thus shorter wavelengths, than the absorbed source light 42. The higher energy of the converted light 46 resulting from an anti-Stokes shift may result from the combining of two or more photons of a lower energy state to create one photon of a higher energy state. This process may be known generally to skilled artisans as photon upconversion. Additionally, the higher energy of the converted light 46 emitted by an anti-Stokes conversion material 30 may be due to dissipation of thermal phonons in a crystal lattice, as will be understood by a person of skill in the art.

A wavelength conversion material 30, as it is defined in regard to the present invention, may include one or more conversion materials. For example, without limitation, the wavelength conversion material 30 may include two types of phosphors to convert a blue source light into yellow and red converted lights. As an additional example, the conversion material 30 may include a first conversion material 30 to perform a Stokes shift and a second conversion material 30 to perform an anti-Stokes shift. For example, the first conversion material 30 may convert the blue light emitted by a blue LED into white light, which may be more visually pleasing to an observer. The second conversion material 30 may convert a source environmental light 48 into blue or ultraviolet light, which may be detected by the blue LED. By including both a Stokes and anti-Stokes conversion material 30, the LED may emit and detect light within a significant range of the visible spectrum with respect to the respective wavelength conversions. Also, with respect to the present example, a Stokes conversion of infrared light and an anti-Stokes conversion of blue light may be inconsequential to the operation, as the conversion may simply convert a portion of the source light 42 into converted light 46 outside of the visible spectrum.

Referring now to FIGS. 31-36, illustrative wavelength ranges will now be discussed in relation to the light emitted and detected by a light emitting semiconductor device 40, such as an LED. The following discussion will be directed to using an LED as the light emitting semiconductor device 40. However, a person of skill in the art will appreciate that additional light emitting semiconductor devices 40 may be included in the lighting system 10, according to an embodiment of the present invention, and without limitation. Additionally, the illustrative waveforms illustrated in FIGS. 31-34 contemplate the emission of illuminating light 44 and the detection of environmental light 48 without the use of a conversion material 30 to perform a wavelength conversion.

Referring now to the illustrative waveforms of FIGS. 31-32, the light emitted and detected by an infrared LED will now be discussed. FIG. 31 illustrates the illuminating light 44 that may be emitted by an illustrative infrared LED, which may include illuminating light 44 characterized by long wavelengths. The wavelength range of the illuminating light 44 emitted by the infrared LEDs may be outside of the visible spectrum. FIG. 32 illustrates the environmental light 48 may be detected by the infrared LED, which may include a wavelength range of environmental light 48 with wavelengths less than the illuminating light 44 emitted by the infrared LED. Since environmental light 48 in the visible spectrum would include light defined by wavelengths shorter than infrared light, the infrared LED may detect substantially the entire wavelength range of environmental light 48 in the visible spectrum.

Referring now to the illustrative waveforms of FIGS. 33-34, the light emitted and detected by a blue LED will now be discussed. FIG. 33 illustrates the illuminating light 44 that may be emitted by the blue LED, which may include illuminating light 44 characterized by relatively short wavelengths. The wavelength range of the illuminating light 44 emitted by the blue LEDs may be included in the visible spectrum, however toward the narrow wavelength range of visible light. FIG. 34 illustrates the environmental light 48 that may be detected by the blue LED, including a small wavelength range of visible light that may include environmental light 48 characterized by shorter wavelengths than the blue illuminating light 44 emitted by the blue LED. Since the blue LED may not detect wavelength longer than the blue light emitted by the blue LED, it may not be able to detect a significant wavelength range of environmental light 48 in the visible spectrum.

Referring now to FIGS. 35-36, the light emitted and detected by a blue LED that includes a conversion material 30 between the LED and the environment will now be discussed. More specifically, a blue LED with a conversion material 30 capable of performing a Stokes shift and an anti-Stokes shift, according to an embodiment of the present invention, will now be discussed. FIG. 35 illustrates the illuminating light 44 that may be emitted by the blue LED, which may include illuminating light 44 characterized by relatively short wavelengths. FIG. 35 additionally may include a wavelength range of illuminating light 44 that has been converted by the conversion material 30 to approximately the wavelength range of yellow light. Skilled artisans will appreciate that the blue source light 42 emitted by the blue LED and the yellow converted light 46 emitted by the conversion material 30 may be combined to create approximately white light.

Referring additionally to FIG. 34, the environmental light 48 that may be detected by the blue LED may include a small wavelength range of visible light, which may include environmental light 48 with wavelengths shorter than the blue illuminating light 44 emitted by the blue LED. However, the wavelength range of detectable environmental light 48 may additionally include environmental light 48 characterized by longer wavelengths than the light natively detectable by the blue LED.

The anti-Stokes conversion material 30 may convert the natively undetectable wavelengths of a environmental source light 42 into converted light 46 detectable by the blue LED. Since the blue LED may detect wavelengths shorter than its emittable blue light that, and since the conversion material 30 may convert the long wavelength light into short wavelength light, the blue LED may then be able to detect a significant wavelength range of the visible spectrum.

Referring now additionally to FIGS. 37-38, an illustrative conversion and detection of a wavelength range of environmental light 48 outside of the detectable spectrum of a blue LED will now be discussed. Skilled artisans will appreciate that the following discussion is provided as an example, in the interest of clarity, and without limitation. Skilled artisans will additionally appreciate that any number of LEDs, or other light emitting semiconductor devices 40, may be used in similar operation, and are intended to be included within the scope of the present invention. Therefore, those of skill in the art will not view embodiments of the present invention to be limited to the inclusion of blue LEDs.

Referring now to FIG. 37, a model environmental light 48 will now be discussed that includes a peak of light to be detected by the lighting system 10, according to an embodiment of the present invention. The aforementioned peak of environmental light 48 is indicated as the point 91. As illustrated in FIGS. 33 and 37, the blue LED may emit illuminating light 44 defined by a shorter wavelength range than the wavelength range of environmental light 48 indicated by point 91. Since the blue LED may not natively detect environmental light 48 with wavelengths longer than the light it emits, the blue LED may not be able to detect the peak of environmental light 48 indicated by point 91 of FIG. 37 without a prior wavelength conversion, such as an anti-Stokes conversion.

The wavelength range of environmental light 48 indicated by point 91 may be absorbed by a wavelength conversion material 30 as source light 42. The wavelength conversion material 30 may then emit a converted light 46 that includes at least part of the peak of light indicated by point 91, but characterized by a lower wavelength range than which the peak of light indicated by point 91 was absorbed by the conversion material 30. This shift of wavelengths is illustrated in FIG. 38. The converted peak of light indicated by point 91 may then be emitted by the conversion material 30 at with shorter wavelengths than the wavelength range of illuminating light 44 emittable by the blue LED, thus allowing the peak of light indicated by point 91 to be detected by the blue LED.

An array 39 of light sources and sensors may be comprised of light emitting semiconductor devices 40, which may perform the operation of the light source and the sensor. More specifically, and without limitation, the array 39 may include a plurality of LEDs configured to operate to emit illuminating light 44 and detect environmental light 48. The array 39 of LEDs may include one or more types of LEDs, configured to emit and detect different wavelength ranges of light. For example, the array 39 may include one or more of a blue LED, monochromatic LED, white LED, infrared LED, and any other light emitting semiconductor device 40. Each LED or other light source included in the array 39 may additionally have a wavelength conversion material 30 located between the respective light source and an environment. The wavelength conversion material 30 may convert the wavelengths of the light transmitted between the light emitting semiconductor device 40 and the environment. As a result, the array 39 may detect a plurality of discrete and/or overlapping wavelength ranges of environmental light 48, which may be analyzed by the controller 61 to determine a condition of the environment.

Additionally, the array 39 may include light sources and sensors, which may be light emitting semiconductor devices 40, in single- or multi-dimensional configurations. For example, an approximately linear length of light emitting semiconductor devices 40 may be included in a one-dimensional array. Additionally, a plane of light emitting semiconductor devices 40 may be included in a two-dimensional array. The plane of light emitting semiconductor devices 40 may be configured in, but not limited to, rectangular or circular arrays. Furthermore, three-dimensional array 39 may include light emitting semiconductor devices 40 located on different planes from one another in the array 39, which may emit illuminating light 44 and detect environmental light 48 from a plurality of directions. In one embodiment, a multi-dimensional array 39 may include a plurality of light emitting semiconductors devices 40 to emit illuminating light 44 in an outward direction, independent of one another. An example of this embodiment may include light emitting semiconductors being located on a surface of a spherical object and configured to emit light in a direction projecting outward from the center of the spherical object.

As another embodiment, the multi-dimensional array 39 may be configured to at least partially enclose a space. An example of this embodiment may include light emitting semiconductors being located on ceilings, walls, floors, and other points of a room. A person of skill in the art will appreciate additional configurations of multi-dimensional arrays 39 to be included in the scope and spirit of the present invention, after having the benefit of this disclosure.

The environmental light 48 detected by the LED, or other light emitting semiconductor device 40, may be communicated to a controller 61 or other signal processing device. A person of skill in the art will appreciate that the term controller 61, as it is defined herein, may describe a single controller 61 that may analyze the environmental light 48 sensed by the LED, light emitting semiconductor device 40, or other sensor, and control the emission of illuminating light 44 by the LED, light emitting semiconductor device 40, or other light source. Additionally, skilled artisans will appreciate an embodiment wherein the term controller 61 may include multiple controllers 61, such as an analysis processor to analyze sensed environmental light 48 and a lighting controller 61 to control emitting illuminating light 44. The analysis processor and the lighting controller 61 may be communicatively connected, and may optionally operate separately or as one monolithic unit.

In one embodiment, information generated by one or more photodetector, or other data comprising light detected by a sensor, may be received and processed by an analysis processor to generating information about the environment. In one embodiment, the processed data may be used to determine or infer information about the environment such as, but not limited to, object detection, location, motion, mass, direction, size, color, heat signature, or other information that may be associated with an object or the environment.

In another embodiment, environmental light 48 sensed by a photodetector or other sensor may be processed by an operatively connected controller 61 or processor 62. The data may be used to control one or more light sources to emit illuminating light 44, which may include data light 45 to be received by a sensor or photodetector. For example, if initial data is sensed by a first sensor, and analyzed by the controller 61 to indicate the presence of an object at a location in the environment, one or more light source may be modulated to confirm object detection, further resolve object features or location, or obtain additional data regarding the environment based on the data sensed by the sensor.

The lighting system 10, according to an embodiment of the present invention, may analyze one or more condition of the environment. For example, the lighting system 10 may analyze whether motion is present in the environment. As another example, the lighting system 10 may determine the luminosity of environmental light 48 included in the environment. The determination of luminosity may be performed generally across all sensed environmental light 48, or specifically with regard to one or more wavelength ranges of the environmental light 48. Additionally, the sensors of the lighting system 10 may be configured to detect the presence of environmental light 48 with a discrete wavelength, such as, for example 445 nanometers.

As previously mentioned, an array 39 may include a plurality of light emitting semiconductor devices 40, such as LEDs, configured to emit and detect light. Skilled artisans will appreciate the use of LEDs in this disclosure is not intended to limit the present invention to including solely LEDs as the light source and/or sensor. The LEDs included in the array 39 may be modulated between states wherein illuminating light 44 is and is not emitted. During the states wherein illuminating light 44 is not being emitted, the LED may be used to detect environmental light 48. The modulation of the LEDs may be controlled by the controller 61.

In one embodiment, the LEDs may be modulated between emitting and detecting light to allow detection of the light emitted by the same LED. This modulation may be performed by the controller 61. To detect its own light, an LED and its corresponding switching circuit would have to switch between emitting illuminating light 44 and detecting environmental light 48 in less time than it would take for the illuminating light 44 to be emitted, reflected from the environment, and detected by the.

Alternatively, one or more LED included in the array 39 may be configured to sense the light emitted by one or more other LED included in the array 39. The timing of the various LEDs included in the array 39 may be controlled by the controller 61. In one embodiment, two or more LEDs in the array 39 may be configured such that at least one LED may receive a desired wavelength range of environmental light 48, which may include light previously or simultaneously emitted by another LED in the array 39. Through matching the wavelength ranges of illuminating light 44 emitted by one LED in the array 39, and environmental light 48 detected by another LED in the array 39, the lighting system 10 may determine a condition of the environment. Additionally, a plurality of LEDs may be included in the array 39 and configured to detect the light reflected from the environment that may have originated from other LEDs in the array 39. As the number of LEDs in the array 39 may increase, the number of conditions detected in the environment may also increase.

Skilled artisans will appreciate that LEDs included in the array 39 may be configured to emit and detect light emitted by any number of additional LEDs in the array 39. In other words, the LEDs need not be paired to emit and detect the same light as one another. Additionally, multiple arrays 39 may be connected through a network 69, allowing one array 39 to detect the light emitted by another array 39. The data relating to the light detected by another array 39 may be intercommunicated between the emitting and detecting arrays across the network 69.

The environmental light 48 detected by the sensors of the array 39 may be transmitted to a controller 61 as data. The controller 61 may concatenate the data to create an image. The resolution of the image detected by the array 39 may be determined relative to the number of points in the environment from which environmental light 48 is detected. For example, a simple one-dimensional array 39 including five forward-facing, linearly-aligned LEDs may be capable of producing an image with a resolution of one pixel by five pixels.

In some embodiments, a higher resolution image may be desired. A high resolution image may be produced, for example, by increasing the number of pixels to be included in the image. Due to the small scale at which semiconductor devices may be produced, a substantial number of light emitting semiconductors may be included in the array 39 to additionally sense environmental light 48 from a plurality of directions, effectively increasing the resolution of the respective image.

Adding additional sensors, such as LEDs, to the array 39 may increase the number of points in the environment to be detected by the array 39. Alternatively, including the sensors on a piezoelectric substrate, which is intended to generally include a plurality of deformable substrate types, may increase the points of an environment that may be sampled by a sensor. By allowing each sensor to detect environmental light 48 from multiple points in an environment, the size requirement of an array 39 needed to detect conditions of an environment with high resolution may be advantageously reduced. Additionally, including a large number of LEDs located on piezoelectric substrates in an array 39 may provide detection of conditions of an environment with increased resolution over sensors located on a fixed substrate.

The array 39 may be connected to, and intercommunicate with, additional arrays 39 as nodes in a network 69. The environmental light 48 sensed by each sensor in the node and analyzed by the controller 61 of the node, may be intercommunicated between the nodes throughout the network 69. By including a plurality of nodes in the network 69, the data detected by each node can be concatenated with data detected from other nodes to increase the resolution at which a condition of the environment with may be determined over the resolution available from a single node. The increased resolution of the environmental light 48 detected at each node may be collectively concatenated to produce a visual representation of one or more condition of the environment.

Where two or more nodes and/or arrays 39 are included in the lighting system 10, the driving time of one node or array 39 may be coordinated with the driving and/or detecting time of another node in the network 69. An example of a driving time may be the PWM timing and phase protocol for driving an array 39 or node for emitting illuminating light 44 and/or detecting environmental light 48. The coordination of this operation may be controlled by a controller 61 communicatively connected to the array 39, light emitting semiconductor device 40, or otherwise included in the node. The coordination may be used to control both emission and detection of light.

An example of visually detecting a condition of the environment will now be discussed. A two-dimensional visual representation of a condition of the environment may be an image. The image may be formed by concatenating the luminosity and/or wavelength data gathered from each point in the environment. Moreover, a plurality of images may be concatenated to create a moving picture, or video, of the environment. The video may be streamed directly to an interface device by transmitting data light 45 and/or using a data transmission protocol known within the art. The video may also be stored in memory 64, wherein it may be accessed, downloaded, and/or viewed concurrent or at a later time.

The images created from the sensed environmental light 48 may also be compared with previously or subsequently created images. For example, sequential images may be compared to detect differences between each image. The difference between the images may be analyzed to detect a condition, such as motion. Additionally, the controller 61 may further analyze the motion detected between a plurality of images to detect the distance and/or velocity of the motion. A person of skill in the art will appreciate that velocity is defined to include the rate and direction in which the position of an object may change. Skilled artisans will also appreciate that the images compared to detect motion, or another condition of the environment, may not be sequential.

The lighting system 10, according to an embodiment of the present invention, may detect the distance between the system 10 and an object in the environment. In one embodiment, the lighting system 10 may tag or indicate light emitted from the light source as marker light 49, which may be detectable by a sensor. The light source and the sensor may, for example, and without limitation, be an LED. Also, the light indicated as marker light 49 may be viewed as a segment of light that includes an identifying characteristic.

Skilled artisans will appreciate that the marker light 49 may be included in illuminating light 44 emitted into the environment and environmental light 48 sensed from the environment. The illuminating light 44 that includes the marker light 49 may be reflected from a point of reflection 50 in the environment, after which it may be received as environmental light 48 by a sensor, such as an LED configured to detect environmental light 48.

In one example, the marker light 49 may include a specific wavelength range as the identifying characteristic. As a specific example, and without limitation, a pulse of marker light 49 may be emitted by an LED into the environment with a wavelength of 485 nanometers. The marker light 49 may be natively emitted or converted by a conversion material 30 to achieve the desired wavelength range that may indicate the marker light 49. An LED operating to detect environmental light 48 may subsequently sense the pulse of marker light 49.

In an additional example, the marker light 49 may include one or more bits of digitally encoded information. This information may identify the segment of marker light 49. The digitally encoded marker light 49 may include a pattern of high and low values, such as zeros and ones, which may be sensed by a sensor and communicated to a controller 61. The digitally encoded marker light 49 sensed in the environmental light 48 may then be compared with the digital encoding of the emitted marker light 49 to determine whether the digitally encoded signal is the same.

The controller 61 may be connected to both the emitting LED and the sensing LED. The controller 61 may detect the delay between the emission of the marker light 49 and the detection of the marker light 49. The controller 61 may analyze the delay to determine the relative distance of an object in the environment.

In some instances, at least one LED may detect the marker light 49 as it is being emitted by another LED included in the lighting system 10, which may be communicated to the controller 61, which may create an error by having effectively having approximately no delay. The controller 61 may perform error detection by determining that the detection of marker light 49 without an accompanying delay may not have been reflected from a point of reflection 50 in the environment. In these instances, the controller 61 may disregard the sensed marker light 49 without an accompanying delay. The controller 61 may then subsequently detect the marker light 49 with an accompanying delay. This delay may be indicative that the marker light 49 has been reflected from a point of reflection 50, which may be due to an object in the environment.

Referring now to FIGS. 39-41, an illustrative operation of detecting a delay using marker light 49 will now be discussed. The block diagram of FIG. 39 and the flow chart 250 of FIG. 40, along with the timeline of FIG. 41, illustrate the operations of flowchart 250 plotted relative to the time of each operation. Starting at Block 251, the delay detecting operation may begin. The marker light 49 may be emitted by light emitting semiconductor device 40, which may be included in an array 39 of light emitting semiconductor devices 40 (Block 252). The marker light 49 may then be reflected from a point of reflection 50 (Block 254). At least part of the reflected marker light 49 may be directed back to the light emitting semiconductor device 40, or array 39 of light emitting semiconductor devices 40, which may detect the light. Additionally, the reflected marker light 49 may be directed to another light emitting semiconductor device 40 included in a network 69 connected node, which may intercommunicate with the node that emitted the marker light 49. The reflected marker light 49 may be included in environmental light 48, which may be sensed by a light emitting semiconductor device 40 (Block 256). The controller 61 may then determine the distance of the object from the lighting system 10 by analyzing the delay (Block 258). The operation may then terminate at Block 259.

As an additional example, in a three-dimensional array 39, the environmental light 48 detected by the sensors of the array 39, or alternatively the sensors included within a node of the network 69, to determine a three-dimensional representation of the environment. The distance of an object detected by sensors included in the array 39 or network 69 may be concatenated to generate a three-dimensional model of the environment. As distances may be calculated from different angles, detail may be added to the three-dimensional model of the environment. Also, the three-dimensional model of the environment may be continually updated as the sensors continue to sample the environment. Like with images and videos, the three-dimensional model of the environment may be observed remotely by additional devices in the network 69.

After the environmental light 48 has been sensed by at least one sensor, which may be an LED included in an array 39, the lighting system 10 may analyze the environmental light 48. A number of signal processing operations have been discussed in the referenced and incorporated U.S. patent application Ser. No. 13/269,222. Additional signal processing operations may be included to recognize one or more pattern relative to the environment.

The data detected and analyzed from a single light emitting semiconductor device 40, a plurality of light emitting semiconductor devices 40 included in an array 39, or a plurality of light emitting semiconductor devices 40 connected through a network 69, can be further processed to extract additional information. Wavelength and intensity information may be distributed throughout a digital neural network for an in-depth analysis and identification of a source of interest. A neural network will be discussed in more detail below.

The controller 61 may analyze the data detected by the sensor, which may be an LED, to identify one or more condition of the environment. A condition of the environment may include objects, substances, or living beings in the environment. In an embodiment, identification may include recognition of one or more object, such as, but not limited to, large vehicle, small vehicle, people, a specific person, animal, substance and other conditions of an environment that could be identified.

The light emitting semiconductor device 40, or another sensor, may sense environmental light 48 including a plurality of wavelength ranges. A dominant wavelength may be included in the wavelength sensed by the lighting system 10. The dominant wavelength may be indicative of a desired condition to be detected in the environment, such as, for example, color. The dominant wavelength may additionally be used to sense the presence of a substance in an environment, as the controller 61 may detect the presence or absence of the dominant wavelength from the sensed environmental light 48.

In an embodiment of the present invention, the dominant wavelength may be defined by the controller 61. The controller 61 may be programmed to detect dominant wavelengths that can be associated with a specific condition to be sensed in the environment. The sensed condition may include the presence of a substance, for example, and without limitation, a gas, biological agent, explosive compound, neurotoxin, element, chemical composition, smog, particulate, or other substance. A person of skill in the art will appreciate additional conditions that may be sensed by detecting the presence or absence of a dominant wavelength, which is intended to be included within the scope of the present invention.

An object may be recognized or identified with various levels of clarity and resolution. For example, in an embodiment that includes a neural network, the resolution of an identified object may be relative to the amount and quality of the information provided to the neural network. A network of many nodes, each node including a controller 61, light source, and sensor, may provide enough resolution to allow for the identification of a person with a medium degree of confidence (80% or above), or a high degree of confidence (95% of above).

An artificial neural network, commonly referred within the art, simply as a neural network, may include a plurality of interconnected nodes to share the collection and processing of data. Each node in a neural network may operate similar to the neurons of a biological neural network, processing information using an interconnected network of simple units. The neural network may use a learning procedure, such as parallel distributed processing, to improve the accuracy of the analysis performed by at least one of the nodes included in the network 69. A person of skill in the art will appreciate additional learning procedures, in substitution or addition to parallel distributed processing, to be included within the scope of the present invention. Additionally, skilled artisans will appreciate additional artificial learning procedures that may analyze a determination to improve the accuracy of subsequent determinations to be included within the scope of the present invention, such as but not limited to, machine learning.

The choice of the neural network for recognizing and identifying an object may be based upon the configuration of the network 69 of nodes, each of which may include a controller 61 and at least one light emitting semiconductor device 40, for example, an LED. The selection process for selecting a type of neural network may begin with a detailed analysis of a certain number of input data streams for LEDs relating to the sensed environmental light 48. The neural network may then focus on determining correlations of LED responses with exposure to their respective light sources. LEDs spaced relatively far apart from each other will likely exhibit low correlation among different LEDs. Conversely, LEDs placed in an array 39 very close to each other may show high correlation numbers. The objective is to find the LEDs with the largest responses and correlations to enable achieving the highest performance in any subsequent neural network.

To operate effectively, a neural network may be trained to recognize different objects. More specifically, a neural network may be trained to identify one object from another of similar, but not identical, characteristics. The training may be performed using various techniques, such as, for example, use of back propagation of gradient-descent computed error corrections for weights and biases. The back propagation technique may involve feed forwarding an input training pattern, computing the associated error between computed outputs and training vector outputs, back propagating the associated errors, and adjusting weights and biases.

In an additional embodiment, machine learning may be used to improve the accuracy of the analysis performed by the controller 61. As will be understood by skilled artisans, machine learning may include a series of analyses performed by a computerized device, such as the controller 61, which may allow the computerized device to evolve its predictions based on empirical data included in memory 64 or detected by sensors. In embodiments of the present invention, the controller 61 of the lighting system 10, or collectively the controllers 61 of each node included in the lighting system 10, may included as the computerized devices to analyze the environmental light 48 data detected by one or more sensor.

The controller 61 may make predictive determinations based on rules that have been dynamically created through data programmed in the memory 64 and the recording of feedback relating to prior determinations. Through inductive inference, the lighting system 10 may classify the sensed data using pattern recognition. This classification may allow the lighting system 10 to learn, or become more likely to automatically recognize, complex patterns. Through machine learning, the lighting system 10 may additionally distinguish between patterns, allowing one or more controller 61 included in the lighting system 10 to make an intelligent prediction on the data received by the sensor.

A person of skill in the art will appreciate that the lighting system 10 of the present invention may include various additional operations and determinations to improve the execution and accuracy of the analysis performed on the environmental light 48 sensed by the sensor and transmitted to the controller 61. As a result, skilled artisans will not limit the learning techniques to the aforementioned examples of neural networks and machine learning. Instead, those of skill in the art will appreciate a plethora of additional branches of advanced computing and artificial intelligence, including analyses based on pattern recognition and error detection, to be included within the scope of the present invention.

As previously mentioned, according to an embodiment of the present invention, the lighting system 10 may include a plurality of nodes connected through a network 69. Each node may include at least one of a light source, sensor, and controller 61. Skilled artisans will appreciate that the light source and the sensor may be included as a light emitting semiconductor device 40, such as an LED. The nodes may intercommunicate with one another through the transmission and receipt of data light 45. If a node receives data light 45 that is addressed or intended for another node, the unintended recipient node may rebroadcast the data to be received by another node, such as the intended node.

The nodes in the network 69 may communicate, for example, by transmitting a digitally encoded data light 45 among the nodes in the network 69. The data light 45 may include modulated or otherwise controlled pulses, which may include transmittable data. The data light 45 may be modulated using pulse width modulation (PWM), pulse interval modulation (PIM), or an additional modulation technique that would be appreciated by those of skill in the art.

According to an embodiment of the present invention, the data transmitted in the data light 45 may be transmitted at a high data rate. To accomplish high data rates, the lighting system 10 may increase the quantity of data transmitted per channel and/or increase the number of channels.

To increase the data transmitter per channel, the data light 45 may be transmitted with an increased modulation frequency signal. The more frequently the data light 45 is be modulated between the active and inactive states, or between logical ones and zeros, the more data may be transmitted to a receiving node in the network 69. To achieve increased frequency modulation, the light source emitting the data light 45 may use rapidly decaying modulation techniques. In embodiments that include an array 39 of light emitting semiconductor devices 40, the rapidly decaying modulation may be accomplished, for example, by distributing the transmission of data light 45 across multiple light sources included in the array 39. The controller 61 of the lighting system 10 may distribute the emission of data light 45 among various light sources. The controller 61 may overlap switching between active and inactive states across multiple light sources, which may advantageously provide faster switching than would be achieved by using a single light source. Additionally, including high speed switches may allow further increased switching, which may correspond to increased data rates.

The data light 45 may include at least one channel through which data may be transmitted. For example, a single channel transmission of data light 45 may occur at or about 445 nanometers. Using a single channel, the theoretical maximum rate at which data light 45 may be transmitted may be bound by the rate at which the single channel may be modulated.

According to an embodiment of the present invention, the data light 45 may be modulated across a plurality of channels. Each channel of data light 45 may be defined respective to a characteristic of that channel, such as the wavelength of light at which the data light 45 is transmitted. Additionally, each channel may be directed to one or more node within the network 69. In multi-channel transmission of data light 45, all channels may be directed to the same node. Alternatively, a number of channels of data light 45 transmitted from a first node may be directed to any number of separate nodes, each of which receiving one or more channels of data light 45. Nodes may address one another sequentially and/or in parallel. In other words, each node may address one or more additional nodes substantially simultaneously by transmitting data light 45 over a plurality of channels.

Referring now to FIGS. 42-43, an example of a five-channel transmission of data light 45 will now be discussed. The five-channel transmission of data light 45 may include five streams of data to be received by another node in the network 69. The five data channels may be transmitted at five different wavelengths of light. The wavelengths of each data channel may be generated by including various conversion materials 30A, 30C, 30D, 30E, and 30F adjacent to one or more light sources, such as light emitting semiconductor devices 40.

More specifically, and provided without limitation, the five channels of data light 45 may be transmitted at 445, 460, 485, 495, and 510 nanometers. These wavelengths may appear visually similar to human observers, yet would be very distinct to a sensor configured to detect the discrete wavelengths. Each channel of data light 45 may be emitted by a respective light source, or wavelength conversion material 30 that may receive and convert the illuminating light 44 from a light source, at the appropriate wavelength. The channels of data light 45 are illustrated in FIG. 43, with each channel correlating to a conversion material 30 applied to the array 39 of lighting emitting semiconductor device of FIG. 42.

Additionally, each sensor may discretely detect the data light 45 at each wavelength respective to the channel it has been emitted. Optionally, the lighting system 10 may use a wavelength conversion material 30 to convert environmental light 48 prior to being detected by the sensor. The detected channels of data light 45 may then be communicated to the controller 61, which may combine the data from each channel to receive the data included in the data light 45.

Skilled artisans will appreciate that embodiments of the present invention may include any number of channels at which data light 45 may be transmitted. Additionally, a person of skill in the art will appreciate that virtually any wavelength, or range of wavelengths, may be used to include light at a given channel. As such, a person of skill in the art will not view the use of three channels, or the specified illustrative wavelengths of each channel, as limiting the present invention in any way.

According to an embodiment of the present invention, the sampling rate at which the environmental light 48 may be detected can be variable. The sampling rate may be varied manually, dynamically, and/or according to a predetermined pattern. For example, if the lighting system 10 detects that minimal changes exist between sampling periods of the environment, the lighting system 10 may decrease the sampling rate at which environmental light 48 is detected. Alternatively, if the lighting system 10 detects a high degree of variance between sampling periods, the lighting system 10 may increase the sampling rate to detect changes in the environment with an increased level of detail.

According to an additional embodiment of the present invention, the data light 45 may be transmitted at one or more bit rate. The bit rate may be adjusted relative to a plurality of factors, including the quantity of data to be transmitted, the quantity of errors detected in the data transmission, distance at which the data may be transmitted, or any number of additional factors that may affect data transmission bit rates.

As an example, the bit rate at which data light 45 is transmitted may be dynamically variable according to the type and quantity of data being transmitted. As an example, the node may transmit a series of images detected from the environment to another node. The image may include varying levels of detail, which may correspond to a varying quantity of data to be transmitted. As the quantity of data needing to be transmitted may vary, so may the bit rate at which the data may be transmitted. Inclusion of a dynamically variable bit rate may allow for the allocation of additional data transmission resources for more complex, and therefore data intensive, portions of a data transmission. Similarly, a dynamically variable bit rate may conserve the amount of data transmitted for relatively simple portions of a data transmission.

According to an embodiment of the present invention, the data included in the data light 45 may be compressed prior to transmission to another node, or other device, in the network 69. Additionally, the data may be decompressed after it has been received by a node. Data compression may reduce the amount of data to be included in the data light 45, further increasing the effective amount of data that may be transmitted using a channel of data light 45. Skilled artisans will appreciate data compression, as many methods of which are known within the art.

According to an embodiment of the present invention, a node may determine its location the environment with respect to other nodes connected in the network 69. A node may also determine the location of other nodes in the environment. Multiple nodes within the network 69 may be aware of a plurality of details relating to additional nodes in the network 69, including the location, operation, and status of the respective nodes.

A node may use a location determining operation, such as, for example, triangulation, to determine its location in an environment. Using triangulation, a node may receive a signal from a plurality of other nodes. The signal may include information to be analyzed by the receiving node to determine its location. For example, a signal used to determine the location of a node may include an identification of the transmitting node, an indication that the signal is transmitted to determine a location, a time stamp from which a transmission delay may be calculated, and/or additional information that would be apparent to a person of skill in the art.

According to an embodiment of the present invention, the lighting system 10 may include one or more wavelength conversion materials 30 that are sensitive to wavelength ranges that may be emitted or absorbed by a substance, such as a biological agent or bomb dust. Such a wavelength conversion material 30 may be used in connection with the sensor, which may be a light emitting semiconductor device 40, to determine a difference between a detected level of an indicative wavelength range and the normal level of an indicative wavelength range. If the difference detected is indicative of the substance, for example, the difference being above a threshold level, the lighting system 10 may generate an alert which may be received by another device connected to the network 69, or a user. Applications for this embodiment may include airports, embassies, government buildings, base camps, or virtually any additional location wherein the detection of a substance in an environment may be desired.

The lighting system 10 may operate to detect the substance in an environment. The lighting system 10 may include a conversion material 30 between the environment and the sensor to convert a difference in luminosity of one or more wavelength of light reflected, emitted, or absorbed from a substance in the environment to be detectable by the sensor. The light source and the sensor may be included as a light emitting semiconductor device 40, such as an LED. In the interest of clarity, the following examples may refer to a light emitting semiconductor device 40, or more specifically an LED, as the light source and sensor. Reference to a light emitting semiconductor device 40 and/or an LED is not intended to be limiting the light source and/or sensor to be included in the present invention. Also, the accompanying waveforms have been provided as relative waveforms, and should not be considered limiting.

The detectable substance may reflect, emit, or absorb light within a wavelength range respective to the substance. A conversion material 30 may be included between the LED and the environment that is sensitive to a wavelength range corresponding with the wavelength range of the detectable substance. Substances may include toxins, biological agents, contaminants, molecules, or virtually any other substance that may absorb or emit a detectable wavelength range of light.

Referring now to FIGS. 44-45, an example of a substance detection operation will now be discussed. Illuminating light 44 may be emitted from a light emitting semiconductor device 40 into the environment. The relative wavelength range of the emitted illuminating light 44 is illustrated in FIG. 45A. At least part of the illuminating light 44 may be reflected from the substance 32 as environmental light 48. However, the substance 32 may absorb at least part of the illuminating light 44, resulting in a wavelength range of illuminating light 44 that was originally emitted by the light emitting semiconductor device 40 not being included in the reflected environmental light 48. The reflected environmental light 48 indicative of a substance 32 is illustrated in FIG. 45C.

The light emitting semiconductor device 40 may detect the environmental light 48, which may be analyzed by the controller 61 to determine a difference between the emitted illuminating light 44 and the detected environmental light 48. The difference is represented in FIG. 45E. The controller 61 may then compare the wavelength range at which the difference of light occurs with information included in the memory to determine which material is present in the environment. Alternatively, the controller 61 may compare the difference of light with information included in the memory of another device connected to the network 69.

Referring now to FIGS. 46-47, an example of a substance detection operation including a wavelength conversion will now be discussed. Illuminating light 44 may be emitted from a light emitting semiconductor device 40 to be received by a conversion 30 material as source light 42. The emitted illuminating light 44 is illustrated in FIG. 47A. The conversion material 30 may convert the source light 42 into a converted light 46, which may be emitted into the environment as illuminating light 44. The converted illuminating light 44, 46 is illustrated in FIG. 47B.

At least part of the illuminating light 44 may be reflected from the substance 32 as environmental light 48. However, the substance 32 may absorb at least part of the illuminating light 44, resulting in a wavelength range of illuminating light 44 that had originally been emitted by the light emitting semiconductor device 40 not being included in the reflected environmental light 48. The partially reflected environmental light 48 indicative of a substance 32 is illustrated in FIG. 47C.

The environmental light 48 indicative of the substance 32 may be received by the conversion material 30 as source light 42 to be converted into converted environmental light 46, 48, which may be received by the light emitting semiconductor device 40. The converted environmental light 46, 48 is illustrated in FIG. 47D. The light emitting semiconductor device 40 may detect the environmental light 48, which may be analyzed by the controller 61 to determine a difference between the emitted illuminating light 44 and the detected environmental light 48. The difference is represented in FIG. 47E. The controller 61 may then compare the wavelength range at which the difference of light occurs with information included in the memory 64 to determine which material may be present in the environment. The controller 61 may consider the preceding wavelength conversion as it performs analysis on difference detected in the environmental light, for which it may compensate. Alternatively, the controller 61 may compare the difference of light with information included in the memory 64 of another device connected to the network 69.

According to an embodiment of the present invention, the lighting system 10 may generate an alert upon the occurrence of an event. The alert may be transmitted to an additional node included in the network 69, an otherwise network connected device, or displayed to an observer. An event that may initiate an alert may involve the detection of a condition in the environment, such as the presence of an object or substance. The event may alternative initiate an alert if a condition rises above a threshold level, which may be predefined or dynamically determined. The communication across the network 69 may be performed digitally. Alternatively, the communication of an alert may be performed by emitting an alerting wavelength, or a wavelength that has been designate to indicate that an alert has been generated. Furthermore, an alert may be communicated as the emission of visual light, for example, flashing red light upon the detection of a hazardous condition in the environment.

According to an embodiment of the present invention, a synchronization signal may be emitted among a plurality of nodes to synchronize the operation of the nodes. For example, the nodes may be synchronized to target, analyze, or confirm analysis of a condition of the environment. Alternatively, the synchronization signal may be used to synchronize the images or other visual representations of the environment. Furthermore, the synchronization signal may synchronize the shared processing efforts across at least part of the nodes included in the network 69. A person of skill in the art will appreciate a plethora of additional synchronization operations that may be performed with a synchronization signal after having the benefit of this disclosure.

According to an embodiment of the present invention, the analysis of the environmental light 48 detected in the environment, or other conditions detected in the by a sensor, may be shared across multiple nodes included in a network 69. The shared analysis of data may be performed, for example, using distributed computing, which would be appreciated by a person of skill in the art. Generally, distributed computing may organize a complex computation into multiple discrete computations, each of which may be distributed to one or more nodes across a network 69 to be performed in parallel. After the discrete computations have been completed, they results may be combined to a result from the complex computation.

According to an embodiment of the present invention, a wavelength conversion material 30 may be included between the light source and the environment to create a biologically affective light. The source light 42 may be a light emitting semiconductor device 40, such as, for example, an LED. The biologically affective light may include one or more wavelength ranges that may induce a biological effect in an organism. As an example, a conversion material 30 may be included to convert a source light 42 into a converted light 46 including wavelengths that increase the production of biological chemicals that affect alertness, such as melatonin.

A non-limiting example of selectively introducing a biologically affective wavelength range into an environment will now be discussed. In this example, the lighting system 10 may detect that a person is present in the environment. The lighting system 10 may make this determination by analyzing information received from detecting the environmental light 48. Such information may include heat signatures, proximate variance, movement, images, videos, patterns, or other detected information. The lighting system 10 may then enable one or more light source with an adjacently located biologically affective conversion material 30 to emit biologically affective converted light 46. The biologically affective light may induce the onset of sleepiness for the people in the environment. Due to the effects of sleepiness, the people in the room may become less alert, slowing response times, and providing for a tactical advantage for any subsequent operations performed in that environment.

The following embodiments are intended to illustrate the components of the present invention in operation, wherein the lighting system 10 may sense one or more condition present in the environment by sensing environmental light 48. A person of skill in the art will appreciate that the following embodiments are included in the interest of clarity, and are not intended to impose any limitations on any of the embodiments the present invention. After having the benefit of this disclosure, a skilled artisan would appreciate additional embodiments consistent with the scope and spirit of the invention described in this disclosure to be included herein.

Referring now to FIGS. 48-51, an embodiment of the lighting system 10 including an array 39 to detect and compare a series of images with moderately low resolution will now be discussed. In this embodiment, the light sources and sensors may be light emitting semiconductor device 40. The light emitting semiconductor devices 40 may be configured in an eight-by-eight square array 39. However, skilled artisans will appreciate that any number of light emitting semiconductor devices 40 may be configured in an array 39 of virtually any shape, as it may be included in single- or multi-dimensional configurations.

Operation of the light emitting semiconductor devices 40 included in the array 39 may be selectable between emitting illuminating light 44 and detecting environmental light 48. The light emitting semiconductor devices 40 may be selectable between emitting and detecting at intervals independent of one another, overlapping intervals, or substantially simultaneously. Additionally, the light emitting semiconductor devices 40 may be selectable between emitting and detecting repeatedly, effectively cycling through periods of light emission and detection.

As one or more light emitting semiconductor device 40 may detect the environmental light 48 in the environment, the light emitting semiconductor device 40 may transmit data regarding the detected environmental light 48 to the controller 61 for analysis. The controller 61 may concatenate each point of data, as may be sensed by the light emitting semiconductor devices 40, to create an image. The image may have a resolution relative to the number of light emitting semiconductor devices 40 included in the array 39 and the number of points in the environment from which environmental light 48 may be sensed by each light emitting semiconductor device 40.

Referring now to FIG. 48, an illustrative image sensed by the lighting system 10 will now be discussed. This illustrative image may have been detected by a fixture located above a target environment, facing downward. The relative luminosity of light detected in the environment, which may be indicative of an object being located in the environment, may be represented by a scale of values. In the present illustrative image, the scale of values ranges from zero to four. However, a person of skill in the art will appreciate that the scale of values may include any number of intervals between a minimum and maximum value.

A plurality of objects may be located in the environment. A first and second object may be located approximately in the top half of the area to be sensed by the lighting system 10. Since the tallest point of the object may be located near the object's center, the amount of light reflected from the environment proximate to the object may be greater than other points wherein the object is not present. Additionally, a third object may be located approximately in the bottom left portion of the area to be sensed by the lighting system 10.

In the example illustrated by FIG. 48, the light emitting semiconductor device 40 may sense a saturating amount of environmental light 48 from the first object at location (3,5), with varying levels of luminosity surrounding the saturated areas. The light emitting semiconductor device 40 may sense a saturating amount of environmental light 48 from the second object at location (6,6), with varying levels of luminosity surrounding the saturated areas. Furthermore, the light emitting semiconductor device 40 may sense a saturating amount of environmental light 48 from the third object at locations (3,1) and (3,2), with varying levels of luminosity surrounding the saturated areas.

The controller 61 may process the levels sensed by the light emitting semiconductor devices included in the array 39 to determine that an object is present in the environment that the lighting system 10 may detect. The controller 61 may then, for example, control the light emitting semiconductor device 40 to increase the emission of illuminating light 44 as a result of an object being present in the environment. The controller 61 may additionally analyze the proximate variance, which may be used to determine the location and movement of the objects, to make a determination of condition in the environment. For example, the controller 61 may determine that the first and second objects are likely humans engaged in a conversation. The lighting system 10 may then enable a microphone, which may be included in, or connected to, the lighting system 10 to sense an additional condition of the environment, such as conversation dialog in the present example. A person of skill in the art will appreciate additional sensors that may sense information from an environment that would be included in the scope of the present invention.

Additionally, in an embodiment of the present invention, the lighting system 10 may communicate the sensed conditions by using the data communications discussed above, such as transmitting data through a series of pulsed light emissions. The lighting system 10 may transmit or relay the information sensed by the additional environmental sensors to one or more additional node, which may be included in the network 69.

The lighting system 10 may continue to sample the environment by sensing the luminosity of environmental light 48 present in the environment. By continually sampling the environment, the controller 61 may analyze the sensed environmental light 48 to make further determinations regarding the conditions of the environment. Additionally, as additional nodes may be added to the network 69, the computational power of the network 69 of nodes may be increased, respectively. This increase of computational power may be accomplished by, for example, distributed computing.

Light emitting semiconductor devices 40 may comprise different semiconductor materials and/or be located adjacent to different conversion materials 30 to detect the luminosity of light relative to different wavelengths. These wavelength based luminosities may be analyzed by the controller 61 to generate an image respective to the different wavelengths. An example of an image representative of multiple wavelength ranges may include a color image. Referring additionally to FIG. 49, the relative luminosity of each sampled point in the environment may be converted into a visual representation, which may use color or shading to represent the luminosity and wavelength levels detected in the environment.

Referring now additionally to FIG. 50, a subsequent image may additionally be sensed by the lighting system 10. The subsequent image may be sensed similar to the sensing operation described in relation to FIG. 48. Referring to FIG. 50, a subsequent sensing operation may sense the objects located in the environment. In this example, the first and second objects may be located approximately in the same positions as wherein the environment was sensed or sampled in the example of FIG. 48. In this subsequent sensing operation, the light emitting semiconductor device 40 may sense a saturating amount of environmental light 48 from the first object at locations (3,5) and (3,6), with varying levels of luminosity surrounding the saturated areas. The light emitting semiconductor device 40 may additionally sense a saturating amount of environmental light 48 from the first object at locations (7,5) and (7,6), with varying levels of luminosity surrounding the saturated areas.

The controller 61 may process the levels sensed by the light emitting semiconductors included in the array 39 to determine that the first and second objects is present in the field in which the lighting system 10 may sense. The controller 61 may additionally determine that the object have not substantially relocated since the last sampling period. The controller 61 may, however, determine that the light reflective patterns of the objects are shifting slightly between each sampling period. The controller 61 may additionally determine, for example, that this shifting pattern is indicative of conversation.

The light emitting semiconductor device 40 may additionally sense a saturating amount of environmental light 48 from the third object at locations (7,1) and (7,2), with varying levels of luminosity surrounding the saturated areas. The relocation of the object between sampling periods may indicate that motion has occurred. The controller 61 may then, for example, determine that a third person or object is patrolling the environment. The lighting system 10 may continue to detect images from the environment, which it may compare to other images to detect further patterns. For example, if the person at the bottom of the screen continually moves in a substantially repeatable pattern, the lighting system 10 may determine with increased confidence that the person is patrolling than simply crossing the environment.

A person of skill in the art will appreciate that the environmental light 48 sensed by the light emitting semiconductor need not saturate the light emitting semiconductor to result in a sensed condition in the environment. The controller 61 may analyze sensed environmental light 48 that does not include a saturating amount of environmental light 48 to determine a condition may exist in the environment. Additionally, a person of skill in the art will appreciate that as the levels of light detected by the light emitting semiconductor may increase, the accuracy of the analysis performed by the controller 61 may correspondingly be increased.

A sensed environment of FIG. 50 may be visually represented as an image, such as illustrated in FIG. 51. The images of FIGS. 49 and 51 may be concatenated into a series of images, for example, to form a video with each image being a frame of the video. The sensed image of FIG. 51 may be compared to one or more other images sensed by the lighting system 10 to determine patterns and differences between the images. The patterns may be analyzed to detect conditions in the environment, such as the presence of an object or person, movement, or other conditions.

According to an embodiment of the present invention, an array 39 of sensors capable of detecting a high resolution image, will now be discussed along with FIGS. 52-54. In this example, an array 39 of light sources and sensors, which may be included as a light emitting semiconductor device 40, may be located on a plane facing a detectable object. In the present example, and without limitation, the array 39 may be included on one or more walls, positioned in alignment to the face of a target person to be detected. A person of skill in the art will appreciate that one or more nodes including additional arrays 39 may be communicatively connected at varying points in the environment to increase the resolution of the images and other conditions detected from the environment.

Referring first to FIG. 52, an array 39 of sensors may detect an object in the environment with an increased level of detail than FIGS. 49 and 51 and other previous examples. As the lighting system 10 may sample an increased number of points in the environment, the resolution of the resulting image may be correspondingly increased. Referring additionally to FIG. 53, a further increased number of points being sampled by the lighting system 10 in the environment may result in a detected image of increasing resolution, which may clearly illustrate defining facial features. The facial features, or other defining features of a target person or object of interest, may be used identify the person or object of interest.

Referring additionally to FIG. 54, an image of further enhanced resolution may be detected with sufficiently enough sensors directed to an object in the environment. As mentioned previously, the sensors may be may be light emitting semiconductor devices 40. The sensors may be configurable to focus on a small area within the environment to better identify the object. As presented in the illustrated example of FIG. 54, the object may be the eye of a person in the environment to be identified. The lighting system 10 may recognize the presence of an eye in the environment, to which defining features of the eye may be detected to identify the person with a high degree of accuracy.

Additionally, the sensors included in an array 39 may be focused on a narrow area in the environment by including a deformable or piezoelectric substrate. For example, the lighting system 10 may detect conditions of an environment generally, indicating that a person exists in the environment. The lighting system 10 may then adjust the sensors to detect environmental light 48 from an angle to focus on a more narrow area within the environment, providing higher resolution. Essentially, according to the present embodiment, the number points from which conditions of the environment may be detected would remain approximately the same, but the area in which the points are concentrated may be reduced to increase the resolution of an image.

The light emitting semiconductor devices 40 of the array 39 may intelligently alternate between emitting illuminating light 44, and sensing environmental light 48. The direction in which each light emitting semiconductor devices 40 faces may be movable, for example, by altering the deformable or piezoelectric substrate. The lighting system 10 may adjust the light emitting semiconductor devices 40 to emit illuminating light 44 in a generally forward direction during a portion of its duty cycle. This forward emission may advantageously make the lighting system 10 appear significantly indistinguishable from a normal lighting device to human observers.

However, during an additional portion of the duty cycle, the lighting system 10 may sense environmental light 48 from a targeted space within the environment. The lighting system may sense environmental light 48 from the targeted space with high resolution, such as to focus on an object in the environment with enhanced wavelength detection. During this focused detection, a substantial number of the light emitting semiconductor devices 40 in the array may be positionable to face the target object in the environment. This targeting operation may allow the lighting system 10 to detect environmental light from an increased number of points within a concentrated space relative to the detectable object. After the wavelength has been detected, the light emitting semiconductor devices 40 may be positioned to again emit an illuminating light 44 in approximately the forward direction.

According to an embodiment of the present invention, wherein the light sources and sensors are located around an environment in three dimensions, the lighting system 10 may detect a three-dimensional representation of the environment. The light sources and sensors may be included as a light emitting semiconductor device 40. A plurality of light emitting semiconductor devices 40 may be distributed throughout the environment to detect the distance of an object in the environment from the light emitting semiconductor device 40. A plurality of light emitting semiconductor devices 40 may determine the distance to an object from a plurality of angles, which may be located on a plurality of planes. The controller 61, or multiple controllers 61 intercommunicating across a network 69, may analyze the distances and angles detected by the light emitting semiconductor devices 40 in the lighting system 10 to determine the position of the object relative to the three-dimensional space of the environment.

More specifically, and without limitation, a plurality of lighting emitting semiconductor devices 40, or a plurality of arrays 39 or nodes including light emitting semiconductor device 40, may be located within the environment to be sensed at differing locations. In this configuration, the light emitting semiconductor devices 40 may be on different planes within the environment to sense environmental light 48 from differing angles and directions. One or more controller 61 may analyze the sensed environmental light 48 from the plurality of angles and directions to construct a multidimensional representation of the environment.

The controller 61 may construct a one-dimensional representation of the environment, collecting information regarding wavelength, chromaticity, and luminosity. The controller 61 may also construct a two-dimensional representation, when may be an image or video, as described above. Additionally, the controller 61 may construct a three-dimensional representation of the environment, showing the relative location of humans, objects, and substances in the environment. The calculations of three-dimensional representations of an environment may be computationally demanding. The computations may be distributed among the controllers 61 included in the network 69. In instances wherein additional processing may be required to render the three-dimensional environments, one or more additional controllers 61 or other processing devices may be communicatively connected to the network 69.

Referring now to FIGS. 55-56, according to an embodiment of the present invention, the environment may be defined as a road or otherwise navigable pathway. Skilled artisans will not view variations of the present embodiment to be restricted to road or other pathways on which a motor vehicle may be operated. The light emitting semiconductor device 40 may be included in one or more streetlight 92 located near the road. The streetlight 92 may be located, for example, at least partially overhead of the road.

Each streetlight 92 may be a node within a network 69 of streetlights 92, which may collectively comprise the lighting system 10. The nodes may intercommunicate with one another by transmitting and receiving data light 45 or using another network communication protocol that would be appreciated by skilled artisans. The streetlights 92 may be able to detect the conditions of the environment, such as the road and objects 35 located on the road. Information relating to conditions of the may be transmitted to a device connected to the network 69. Each node included in the network 69 may detect conditions in an area of the environment located within view of the node. A plurality of nodes in the network 69 may communicate with one another such that they are aware of the conditions sensed by the other nodes, defining a field of view 93.

As a specific and non-limiting example, presented in the interest of clarity and without the intent to limit the present invention in any way, FIGS. 55-56 illustrate the use of streetlights 92 as nodes in a network 69. The streetlights 92 may detect an object 35, such as a tank in the present example, in the field of view 93. The streetlights 92 may be programmed to generate an alert upon sensing a tank on the road, which may be communicated to a node or device connected to the network 69 intended to receive the alert. The intended recipient node may be located, for example, in a town away from the sensing street light 92, in a base camp, or included in another vehicle on the road.

Assuming the intended recipient node is a personnel carrier on the road headed in the direction of the tank, the lighting system 10 may alert the personnel carrier that the present route may be dangerous. The personnel carrier may include one or more node, for example, in the headlights of the personnel carrier. The headlight nodes may receive data light 45 broadcast from one or more streetlight 92 lining the road. An interface device onboard the personnel carrier may receive the alert, warning its occupants of the potential danger ahead and optionally suggesting an alternative route.

Skilled artisans will appreciate additional examples wherein the environment may include virtually any area or space, such as, for example, a room, base camp, ship, or city. Additionally, tracking of one or more objects 35 in the environment may be desired. The tracking may include geographic location information, operational status information, or any other information that may be associated with the object 35. For example, an operation command center may desire to track the location and status of a personnel carrier across a city. The personnel carrier may transmit data light 45 through its headlights, which may be received and distributed by the network 69 of streetlights 92 located throughout the city. The data light may be repeated and/or relayed until it may be received by the operation command center. The data light 45 may include information relating to the proximate location, fuel level, number of passengers, speed, or virtually any other communicable information relating to the personnel carrier.

According to an embodiment of the present invention, the lighting system 10 may include night vision operation. The light emitting semiconductor devices 40 included in the lighting system 10 may broadcast a light that is outside of the spectrum of light that is visible to humans, such as infrared or ultraviolet light. Additional conditions of the environment may also be detected, such as heat signatures, by emitting and detecting non-visible light.

According to an embodiment of the present invention, one or more array 39 included in the lighting system 10 may include a sensor, and not a light source. A light emitting semiconductor device 40 may be used as the sensor, however it may be configured or controlled to not emit illuminating light 44. The array 39 of sensors may detect environmental light 48 of various wavelengths, such as, but not limited to, infrared light. Skilled artisans will appreciate that infrared light may be indicative of heat signatures, which may relate to one or more object 35 detected in the environment.

According to an embodiment of the present invention, a low latency power supply may be included in the lighting system 10 to supply power to the controller 61, one or more light source, and any additional component that may be included in the lighting system 10. The power supply may have a switching latency equal to or less than that of the slight sources included in the lighting system 10, such that the power supply does not restrict the switching speed, and thus potentially the sampling rate of the environment and/or the transmission speed of data included in the data light 45. Additional efficient electronic components, which be defined by high switching rates and/or low decay periods, may be included in lighting system 10. Additionally, fast decay phosphors, fluorescent, or other wavelength conversion materials 30 may be used in the lighting system 10 to provide fast switching between emission and detection of light for each light source.

According to an embodiment of the present invention, additional devices may be connected to the network 69. The additional devices may communicate with one or more node included in the network 69. An additional device may communicate with the node using data light 45 or another network communication protocol that would be appreciated by a skilled artisan. Examples of additional device connected to the network 69 may include, but are not limited to, a flashlight, keychain, watch, headlight, router, television, computer, pen, or virtually any other device that may include a sensor, controller, memory, and optionally a light source.

Many modifications and other embodiments of the invention will come to the mind of one skilled in the art having the benefit of the teachings presented in the foregoing descriptions and the associated drawings. Therefore, it is understood that the invention is not to be limited to the specific embodiments disclosed, and that modifications and embodiments are intended to be included within the scope of the appended claims. 

What is claimed is:
 1. A lighting system comprising: a light source included in an array to emit illuminating light; a sensor included in the array to sense environmental light from an environment; a controller operatively connected to the sensor to analyze the environmental light that is sensed and operatively connected to the light source to control emitting the illuminating light; wherein the controller analyzes the environmental light to detect or generate data relating to a condition of the environment, the data being transmittable in data light defined by at least one data wavelength, wherein the at least one data wavelength is defined relative to the illuminating light; wherein the data is transmittable by the light source included in the array; wherein the sensor selectively senses a dominant wavelength in the environmental light that is defined by the controller; wherein the sensor selectively senses a plurality of dominant wavelengths in the environmental light; wherein at least a part of the plurality of dominant wavelengths are concatenated to define the data relating to the condition in the environment; wherein the controller receives the data using the sensor; wherein the controller analyzes the data; wherein the controller controls transmitting the data light from the light source; wherein the controller designates at least a part of the illuminating light as a marker light, wherein the light source is selectively operable; wherein the sensor is selectively operable; wherein the illuminating light is selectively emitted from the light source in a plurality of directions; wherein the controller controls the light source to emit the illuminating light including the marker light to the environment; wherein the illuminating light is reflected from a point of reflection in the environment as the environmental light, the environmental light continuing to include the marker light; wherein the environmental light is received by the sensor from the plurality of directions; wherein the sensor senses the environmental light including the marker light; wherein the controller calculates a delay between emitting the marker light and sensing the marker light; and wherein the controller analyzes the delay to determine a distance between the array and the point of reflection.
 2. The lighting system of claim 1 wherein the data relating to the condition in the environment includes an image.
 3. The lighting system of claim 2 wherein the image is included in a series of images; and wherein the series of images are concatenated to create a video.
 4. The lighting system of claim 2 wherein the data includes a plurality of images; and wherein the plurality of images are compared to determine a proximate variance of an object among the plurality of images.
 5. The lighting system of claim 4 wherein the proximate variance is analyzed by the controller to determine movement of the object.
 6. The lighting system of claim 5 wherein the movement is analyzed by the controller to determine velocity of the movement.
 7. The lighting system of claim 1 wherein the array includes a plurality of sensors; wherein each sensor included in the plurality of sensors is sensitive to at least one wavelength respective to the each sensor; wherein each sensor is selectively operable.
 8. The lighting system of claim 1 wherein the light source and the sensor are included as a light emitting semiconductor device; wherein the light emitting semiconductor device is selectively operable between a sensing operation and an emitting operation, the sensing operation being defined by the light emitting semiconductor device sensing the environmental light, and the emitting operation being defined by the light emitting semiconductor device emitting the illuminating light.
 9. The lighting system of claim 8 wherein the array includes a plurality of light emitting semiconductor devices.
 10. The lighting system of claim 8 further comprising a switching circuit to alternate the light emitting semiconductor device between the sensing operation and the emitting operation.
 11. The lighting system of claim 8 wherein the light emitting semiconductor device emits the illuminating light and receives the environmental light substantially simultaneously, the light emitting semiconductor device including a light emitting diode to emit the illuminating light and a photodiode to sense the environmental light, the light emitting diode being operable as the photodiode.
 12. The lighting system of claim 11 wherein the controller analyzes the environmental light by measuring a drive voltage of the light emitting semiconductor device, determining a difference between a measured voltage across the light emitting semiconductor device and the drive voltage, and performing time-domain matching of the measured voltage and the environmental light using cross-correlation.
 13. The lighting system of claim 1 further comprising: a network of nodes, each of the nodes in the network of nodes including the light source, the sensor, and the controller; wherein each node in the network of nodes is proximately aware of an additional node in the network; wherein the delay is analyzed by a node in the network to determine the distance between the node and the point of reflection, wherein the distance is intercommunicated within the network by transmitting and receiving the data light; wherein the condition in the environment is determined by analyzing the distance calculated by at least a portion of the nodes in the network.
 14. The lighting system of claim 13 wherein the controller analyzes the distance calculated by at least a portion of the nodes in the network to determine a multidimensional arrangement of the condition in the environment.
 15. The lighting system of claim 1 wherein the dominant wavelength is indicative of a substance present in the environment.
 16. The lighting system of claim 1 wherein the controller controls the array to emit an alert upon sensing an event.
 17. The lighting system of claim 1 wherein the array includes a plurality of light sources; and wherein at least a portion of the light sources included in the array are selected from a group consisting of monochromatic light emitting diodes (LED), white light emitting diodes (LED), and infrared light (IR) emitting diodes (LED).
 18. The lighting system of claim 1 further comprising a network of nodes, each node including the light source, the sensor, and the controller; wherein the nodes intercommunicate by transmitting and receiving an electromagnetic signal.
 19. The lighting system of claim 18 wherein at least a portion of the nodes in the network perform analysis using distributed computing.
 20. The lighting system of claim 18 wherein at least a portion of the nodes in the network synchronize by including a synchronization signal in the electromagnetic signal.
 21. The lighting system of claim 1 wherein at least a part of the illuminating light selectively includes a biological affective wavelength to affect an object in the environment.
 22. The lighting system of claim 1 wherein the data light is defined by a plurality of data wavelengths; wherein the data is transmittable at the plurality of data wavelengths; and wherein a quantity of data wavelengths included in the data light correlates with a bandwidth at which the data is transmittable.
 23. The lighting system of claim 1 wherein the data light includes at least one addressing bit to address the nodes intended to receive the data.
 24. The lighting system of claim 1 wherein the data included in the data light includes at least one error detection bit.
 25. The lighting system of claim 19 wherein feedback regarding an analysis performed by the controller is stored in a memory; wherein the feedback from the analysis is intercommunicated within the network.
 26. The lighting system of claim 25 wherein the feedback is analyzed using machine learning.
 27. The lighting system of claim 25 wherein the feedback is analyzed using a neural network.
 28. The lighting system of claim 1 wherein feedback regarding a prior analysis performed by the controller is stored in a memory; wherein the controller receives the feedback regarding the prior analysis from the memory; and wherein the controller analyzes the feedback regarding the prior analysis to perform a subsequent analysis.
 29. The lighting system of claim 28 wherein the subsequent analysis is performed using machine learning.
 30. The lighting system of claim 1 further comprising a wavelength conversion material between the array and the environment to absorb at least part of a source light and emit a converted light having a converted wavelength range, the source light being received and absorbed by the wavelength conversion material, and the converted light being emitted by the wavelength conversion material.
 31. The lighting system of claim 30 wherein the wavelength conversion material is selected from a group consisting of a fluorescent material, a luminescent material, and a phosphorescent material.
 32. The lighting system of claim 30 wherein the converted wavelength range of the converted light includes a variable dominant wavelength respective to the condition in the environment; wherein the dominant wavelength is indicative of a substance in the environment; and wherein the controller correlates the dominant wavelength with the substance.
 33. The lighting system of claim 32 wherein the substance is selected from a group consisting of an object, element, compound, particulate, and biological agent.
 34. The lighting system of claim 30 wherein the illuminating light is received by the wavelength conversion material as the source light; wherein the wavelength conversion material converts the source light to the converted light; and wherein the converted light is emitted by the wavelength conversion material within the converted wavelength range.
 35. The lighting system of claim 30 wherein the environmental light is received by the wavelength conversion material as the source light; wherein the wavelength conversion material converts the source light to the converted light; and wherein the converted light is received by the sensor within the converted wavelength range.
 36. The lighting system of claim 30 wherein the converted wavelength range includes shorter wavelengths than the source wavelength range; and wherein the wavelength conversion material converts the source light to the converted light by performing an anti-Stokes shift.
 37. The lighting system of claim 30 wherein the converted wavelength range includes longer wavelengths than the source wavelength range; and wherein the wavelength conversion material converts the source light to the converted light by performing a Stokes shift.
 38. The lighting system of claim 1 wherein the controller is operatively connected to a voltage sensor to sense an open circuit voltage across the sensor.
 39. The lighting system of claim 1 wherein the data light transmits the data using an operation selected from a group consisting of pulse width modulation (PWM), pulse amplitude modulation (PAM), intensity modulation, color sequencing, and duty cycle variation.
 40. The lighting system of claim 1 wherein a sample rate at which the data is transmitted in the data light is dynamically adjustable by the controller; and wherein an increased sample rate correlates with an increased resolution sensed by the array.
 41. The lighting system of claim 1 wherein the data is included in the data light digitally.
 42. The lighting system of claim 1 wherein the data included in the data light is encrypted.
 43. The lighting system of claim 1 further comprising a power supply to drive the array.
 44. The lighting system of claim 1 wherein the light source is operable in a pulsed mode.
 45. The lighting system of claim 1 wherein the controller processes the environmental light to remove noise.
 46. The lighting system of claim 1 wherein the controller characterizes luminosity of the environmental light.
 47. The lighting system of claim 1 wherein the array includes a piezoelectric substrate.
 48. A lighting system comprising: a network of nodes, wherein each node in the network of nodes is proximately aware of an additional node in the network, each node including: a sensor to sense environmental light from an environment; a controller operatively connected to the sensor to detect or generate data relating to a condition of the environment based on the environmental light that is sensed by the sensor; and a wavelength conversion material between the node and the environment to absorb at least part of a source light and emit a converted light having a converted wavelength range, the source light being received and absorbed by the wavelength conversion material, and the converted light being emitted by the wavelength conversion material wherein the sensor selectively senses a plurality of dominant wavelengths in the environmental light; wherein at least a part of the plurality of dominant wavelengths are concatenated by the controller to define the data; wherein the controller analyzes the data; wherein the sensor is sensitive to a dominant wavelength included in the plurality of dominant wavelengths; wherein the environmental light is received by the sensor from a plurality of directions.
 49. The lighting system of claim 48 wherein the data includes an image.
 50. The lighting system of claim 49 wherein the image is included in a series of images; and wherein the series of images are concatenated to create a video.
 51. The lighting system of claim 48 wherein the data includes a plurality of images; and wherein the plurality of images are compared to determine a proximate variance of an object among the plurality of images.
 52. The lighting system of claim 51 wherein the proximate variance is analyzed by the controller to determine movement of the object.
 53. The lighting system of claim 52 wherein the movement of the object is analyzed by the controller to determine velocity of the movement.
 54. The lighting system of claim 48 wherein the dominant wavelength is indicative of a substance present in the environment.
 55. The lighting system of claim 48 wherein at least a portion of the nodes in the network perform analysis using distributed computing.
 56. The lighting system of claim 48 wherein the nodes intercommunicate by transmitting and receiving an electromagnetic signal; and wherein at least a portion of the nodes in the network synchronize by including a synchronization signal in the electromagnetic signal.
 57. The lighting system of claim 48 wherein feedback regarding an analysis performed by the controller is stored in a memory; wherein the feedback from the analysis is intercommunicated within the network.
 58. The lighting system of claim 57 wherein the feedback is analyzed using machine learning.
 59. The lighting system of claim 57 wherein the feedback is analyzed using a neural network.
 60. The lighting system of claim 48 wherein feedback regarding a prior analysis performed by the controller is stored in a memory; wherein the controller receives the feedback regarding the prior analysis from the memory; and wherein the controller analyzes the feedback regarding the prior analysis to perform a subsequent analysis.
 61. The lighting system of claim 60 wherein the subsequent analysis is performed using machine learning.
 62. The lighting system of claim 48 wherein the wavelength conversion material is selected from a group consisting of a fluorescent material, a luminescent material, and a phosphorescent material.
 63. The lighting system of claim 48 wherein the converted wavelength range of the converted light includes a variable dominant wavelength respective to the condition in the environment; wherein the dominant wavelength is indicative of a substance in the environment; and wherein the controller correlates the dominant wavelength with the substance.
 64. The lighting system of claim 63 wherein the substance is selected from a group consisting of an object, element, compound, particulate, and biological agent.
 65. The lighting system of claim 48 wherein the environmental light is received by the wavelength conversion material as the source light; wherein the wavelength conversion material converts the source light to the converted light; and wherein the converted light is received by the sensor within the converted wavelength range.
 66. The lighting system of claim 48 wherein the converted wavelength range includes shorter wavelengths than the source wavelength range; and wherein the wavelength conversion material converts the source light to the converted light by performing an anti-Stokes shift.
 67. The lighting system of claim 48 wherein the controller is operatively connected to a voltage sensor to sense an open circuit voltage across the sensor.
 68. The lighting system of claim 48 wherein at least a portion of the nodes in the network of nodes processes the environmental light to remove noise.
 69. The lighting system of claim 48 wherein at least a portion of the nodes in the network of nodes characterizes luminosity of the environmental light.
 70. The lighting system of claim 48 wherein at least a portion of the nodes in the network of nodes includes a piezoelectric substrate.
 71. The lighting system of claim 48 further comprising: a light source to emit illuminating light; wherein the controller is operatively connected to the light source to control emitting the illuminating light; wherein the data analyzed by the controller is transmittable in data light defined by at least one data wavelength, wherein the at least one data wavelength is defined relative to the illuminating light; wherein the data is transmittable by the light source; wherein the controller controls transmitting the data light from the light source; and wherein the illuminating light is selectively emitted from the light source in a plurality of directions.
 72. The lighting system of claim 71 wherein the light source in each of the nodes is included in an array to be selectively enabled and disabled by the controller; wherein the array includes a plurality of light sources; wherein each light source included in the plurality of light sources emits at least one wavelength respective to each light source; and wherein the plurality of light sources is selectively operable.
 73. The lighting system of claim 72: wherein the sensor in each of the nodes is included in the array to be selectively enabled and disabled by the controller; wherein the array includes a plurality of sensors; wherein each sensor included in the plurality of sensors is sensitive to at least one wavelength respective to the each sensor; wherein the plurality of sensors is selectively operable.
 74. The lighting system of claim 72 wherein the light source and the sensor are included as a light emitting semiconductor device; wherein the light emitting semiconductor device is selectively operable between a sensing operation and an emitting operation, the sensing operation being defined by the light emitting semiconductor device sensing the environmental light, and the emitting operation being defined by the light emitting semiconductor device emitting the illuminating light; wherein the array includes a plurality of light emitting semiconductor devices.
 75. The lighting system of claim 71 wherein the controller designates at least a part of the illuminating light as a marker light; wherein the controller controls the light source to emit the illuminating light including the marker light to the environment; wherein the illuminating light is reflected from a point of reflection in the environment as the environmental light, the environmental light continuing to include the marker light; wherein the sensor senses the environmental light including the marker light; wherein the controller calculates a delay between emitting the marker light and sensing the marker light; and wherein the controller analyzes the delay to determine a distance between the array and the point of reflection.
 76. The lighting system of claim 75 wherein the delay is analyzed by a node in the network of nodes to determine the distance between the node and the point of reflection; wherein the distance is intercommunicated within the network by transmitting and receiving the data light; and wherein the condition in the environment is determined by analyzing the distance calculated by at least a portion of the nodes in the network.
 77. The lighting system of claim 76 wherein the controller analyzes the distance calculated by at least a portion of the nodes in the network to determine a multidimensional arrangement of the condition in the environment.
 78. The lighting system of claim 71 wherein the controller controls the light source to emit an alert upon the sensor sensing an event.
 79. The lighting system of claim 71 wherein the light source and the sensor are included as a light emitting semiconductor device; wherein the light emitting semiconductor device is selectively operable between a sensing operation and an emitting operation, the sensing operation being defined by the light emitting semiconductor device sensing the environmental light, and the emitting operation being defined by the light emitting semiconductor device emitting the illuminating light; and further comprising a switching circuit to alternate the light emitting semiconductor device between the sensing operation and the emitting operation.
 80. The lighting system of claim 79 wherein the light emitting semiconductor device emits the illuminating light and receives the environmental light substantially simultaneously, the light emitting semiconductor device including a light emitting diode to emit the illuminating light and a photodiode to sense the environmental light, the light emitting diode being operable as the photodiode.
 81. The lighting system of claim 80 wherein the controller analyzes the environmental light by measuring a drive voltage of the light emitting semiconductor device, determining a difference between a measured voltage across the light emitting semiconductor device and the drive voltage, and performing time-domain matching of the measured voltage and the environmental light using cross-correlation.
 82. The lighting system of claim 71 wherein at least a portion of the plurality of light sources included in the array are selected from a group consisting of monochromatic light emitting diodes (LED), white light emitting diodes (LED), and infrared light (IR) emitting diodes (LED).
 83. The lighting system of claim 71 wherein at least a part of the illuminating light selectively includes a biological affective wavelength to affect an object in the environment.
 84. The lighting system of claim 71 wherein the data light is defined by a plurality of data wavelengths; wherein the data is transmittable at the plurality of data wavelengths; and wherein a quantity of data wavelengths included in the data light correlates with a bandwidth at which the data is transmittable.
 85. The lighting system of claim 71 wherein the data light includes at least one addressing bit to address the nodes intended to receive the data.
 86. The lighting system of claim 71 wherein the data included in the data light includes at least one error detection bit.
 87. The lighting system of claim 71 further comprising a wavelength conversion material between the node and the environment to absorb at least part of a source light and emit a converted light having a converted wavelength range, the source light being received and absorbed by the wavelength conversion material, and the converted light being emitted by the wavelength conversion material; wherein the illuminating light is received by the wavelength conversion material as the source light; wherein the wavelength conversion material converts the source light to the converted light; and wherein the converted light is emitted by the wavelength conversion material within the converted wavelength range.
 88. The lighting system of claim 87 wherein the converted wavelength range includes longer wavelengths than the source wavelength range; and wherein the wavelength conversion material converts the source light to the converted light by performing a Stokes shift.
 89. The lighting system of claim 71 wherein the data light transmits the data using an operation selected from a group consisting of pulse width modulation (PWM), pulse amplitude modulation (PAM), intensity modulation, color sequencing, and duty cycle variation.
 90. The lighting system of claim 71 wherein a sample rate at which the data is transmitted in the data light is dynamically adjustable by the controller; and wherein an increased sample rate correlates with an increased resolution sensed by the node.
 91. The lighting system of claim 71 wherein the data is included in the data light digitally.
 92. The lighting system of claim 71 wherein the data included in the data light is encrypted.
 93. The lighting system of claim 71 wherein the light source is operable in a pulsed mode.
 94. The lighting system of claim 48 further comprising a power supply to drive each of the nodes in the network of nodes.
 95. A method for using a lighting system that comprises a light source included in an array to emit illuminating light, a sensor included in the array to sense environmental light from an environment, and a controller operatively connected to the sensor to analyze the environmental light that is sensed and operatively connected to the light source to control emitting the illuminating light, the method comprising: analyzing the environmental light to detect or generate data relating to a condition of the environment, the data being transmittable in data light by the light source included in the array and defined by at least one data wavelength, wherein the at least one data wavelength is defined relative to the illuminating light; selectively sensing a plurality of dominant wavelengths in the environmental light that is defined by the controller, concatenating at least a part of the plurality of dominant wavelengths to define the data relating to the condition in the environment; using the controller to receive the data using the sensor; using the controller to analyze the data; using the controller to control transmitting the data light from the light source; selectively operating the light source; selectively operating the sensor; designating at least a part of the illuminating light as a marker light; selectively emitting the illuminating light from the light source in a plurality of directions to the environment so that at least part of the illuminating light is reflected from a point of reflection in the environment as the environmental lightm the environmental light continuing to include the marker light; receiving the environmental light from the plurality of directions calculating a delay between emitting the marker light and sensing the marker light; and analyzing the delay to determine a distance between the array and the point of reflection.
 96. The method of claim 95 wherein the data relating to the condition in the environment includes an image.
 97. The method of claim 96 wherein the image is included in a series of images; and further comprising concatenating the series of images to create a video.
 98. The method of claim 96 wherein the data includes a plurality of images; and further comprising comparing the plurality of images to determine a proximate variance of an object among the plurality of images.
 99. The method of claim 98 further comprising analyzing the proximate variance to determine movement of the object.
 100. The method of claim 99 further comprising analyzing the movement to determine velocity of the movement.
 101. The method of claim 95 wherein the array includes a plurality of sensors; wherein each sensor included in the plurality of sensors is sensitive to at least one wavelength respective to the each sensor; and further comprising selectively operating the plurality of sensors.
 102. The method of claim 95 wherein the light source and the sensor are included as a light emitting semiconductor device; and further comprising selectively operating the light emitting semiconductor device between a sensing operation and an emitting operation, the sensing operation being defined by the light emitting semiconductor device sensing the environmental light, and the emitting operation being defined by the light emitting semiconductor device emitting the illuminating light.
 103. The method of claim 102 wherein the array includes a plurality of light emitting semiconductor devices.
 104. The method of claim 102 further comprising alternating the light emitting semiconductor device between the sensing operation and the emitting operation.
 105. The method of claim 102 wherein the light emitting semiconductor device includes a light emitting diode to emit the illuminating light and a photodiode to sense the environmental light; and further comprising emitting the illuminating light and receiving the environmental light substantially simultaneously, the light emitting diode being operable as the photodiode.
 106. The method of claim 102 further comprising analyzing the environmental light by measuring a drive voltage of the light emitting semiconductor device, determining a difference between a measured voltage across the light emitting semiconductor device and the drive voltage, and performing time-domain matching of the measured voltage and the environmental light using cross-correlation.
 107. The method of claim 95 wherein the lighting system includes a network of nodes, each of the nodes in the network of nodes including the light source, the sensor, and the controller, wherein each node in the network of nodes is proximately aware of an additional node in the network, wherein the method further comprises: analyzing the delay by a node to determine the distance between the node and the point of reflection, intercommunicating the distance within the network by transmitting and receiving the data light; determining the condition in the environment by analyzing the distance calculated by at least a portion of the nodes in the network.
 108. The method of claim 107 further comprising analyzing the distance calculated by at least a portion of the nodes in the network to determine a multidimensional arrangement of the condition in the environment.
 109. The method of claim 107 wherein the data light is defined by a plurality of data wavelengths; and further comprising transmitting the data at the plurality of data wavelengths, wherein a quantity of data wavelengths included in the data light correlates with a bandwidth at which the data is transmittable.
 110. The method of claim 107 wherein the data light includes at least one addressing bit to address the nodes intended to receive the data.
 111. The method of claim 95 wherein the dominant wavelength is indicative of a substance present in the environment.
 112. The method of claim 95 further comprising controlling the array to emit an alert upon sensing an event.
 113. The method of claim 95 wherein the array includes a plurality of light sources; and wherein at least a portion of the light sources included in the array are selected from a group consisting of monochromatic light emitting diodes (LED), white light emitting diodes (LED), and infrared light (IR) emitting diodes (LED).
 114. The method of claim 95 wherein the lighting system further comprises a network of nodes, each node including the light source, the sensor, and the controller; wherein the nodes intercommunicate by transmitting and receiving an electromagnetic signal.
 115. The method of claim 114 wherein at least a portion of the nodes in the network perform analysis using distributed computing.
 116. The method of claim 114 wherein at least a portion of the nodes in the network synchronize by including a synchronization signal in the electromagnetic signal.
 117. The method of claim 114 further comprising storing feedback regarding an analysis performed by the controller in a memory; and intercommunicating the feedback from the analysis within the network.
 118. The method of claim 117 further comprising analyzing the feedback using machine learning.
 119. The method of claim 117 further comprising analyzing the feedback using a neural network.
 120. The method of claim 95 further comprising affecting an object in the environment by selectively including a biological effective wavelength in at least a part of the illuminating light.
 121. The method of claim 95 wherein the data included in the data light includes at least one error detection bit.
 122. The method of claim 95 further comprising storing feedback regarding a prior analysis performed by the controller in a memory; and analyzing the feedback regarding the prior analysis to perform a subsequent analysis.
 123. The method of claim 122 wherein the subsequent analysis is performed using machine learning.
 124. The method of claim 95 wherein a wavelength conversion material is positioned between the array and the environment; further comprising absorbing at least part of a source light and emitting a converted light having a converted wavelength range, the source light being received and absorbed by the wavelength conversion material, and the converted light being emitted by the wavelength conversion material.
 125. The method of claim 124 wherein the wavelength conversion material is selected from a group consisting of a fluorescent material, a luminescent material, and a phosphorescent material.
 126. The method of claim 124 wherein the converted wavelength range of the converted light includes a variable dominant wavelength respective to the condition in the environment; wherein the dominant wavelength is indicative of a substance in the environment; and wherein the controller correlates the dominant wavelength with the substance.
 127. The method of claim 126 wherein the substance is selected from a group consisting of an object, element, compound, particulate, and biological agent.
 128. The method of claim 124 further comprising receiving the illuminating light by the wavelength conversion material as the source light; converting the source light to the converted light; and emitting the converted light the converted wavelength range.
 129. The method of claim 124 further comprising receiving the environmental light by the wavelength conversion material as the source light; converting the source light to the converted light; and receiving the converted light by the sensor within the converted wavelength range.
 130. The method of claim 124 wherein the converted wavelength range includes shorter wavelengths than the source wavelength range; and wherein the wavelength conversion material converts the source light to the converted light by performing an anti-Stokes shift.
 131. The method of claim 124 wherein the converted wavelength range includes longer wavelengths than the source wavelength range; and wherein the wavelength conversion material converts the source light to the converted light by performing a Stokes shift.
 132. The method of claim 95 wherein the controller is operatively connected to a voltage sensor to sense an open circuit voltage across the sensor.
 133. The method of claim 95 further comprising transmitting the data using an operation selected from a group consisting of pulse width modulation (PWM), pulse amplitude modulation (PAM), intensity modulation, color sequencing, and duty cycle variation.
 134. The method of claim 95 further comprising dynamically adjusting a sample rate at which the data is transmitted; and wherein the sample rate correlates with a resolution sensed by the array.
 135. The method of claim 95 further comprising including data in the data light digitally.
 136. The method of claim 95 further comprising encrypting the data included in the data light.
 137. The method of claim 95 wherein the lighting system further comprises a power supply to drive the array.
 138. The method of claim 95 further comprising operating the light source in a pulsed mode.
 139. The method of claim 95 further comprising processing the environmental light to remove noise.
 140. The method of claim 95 further including characterizing characterizes luminosity of the environmental light using the controller.
 141. The method of claim 95 wherein the array includes a piezoelectric substrate.
 142. A method of using a lighting system comprising a network of nodes, each node including a light source to emit illuminating light, a sensor to sense environmental light from an environment and a controller operatively connected to the sensor to analyze the environmental light that is sensed and operatively connected to the light source to control emitting the illuminating light, the method comprising: analyzing the environmental light to detect or generate data relating to a condition of the environment, the data being transmittable in data light defined by at least one data wavelength, wherein the at least one data wavelength is defined relative to the illuminating light; using the light source to transmit the data; selectively sensing a plurality of dominant wavelength in the environmental light defined by the controller, wherein at least a part of the plurality of dominant wavelengths are concatenated to define the data relating to the condition in the environment; receiving and analyzing the data; transmitting the data light from the light source; selectively emitting the illuminating light from the light source in a plurality of directions; receiving the environmental light from the plurality of directions; and controlling the light source to emit an alert upon the sensor sensing an event; wherein each node in the network of nodes is proximately aware of an additional node in the network.
 143. The method of claim 142 wherein the data relating to the condition in the environment includes an image.
 144. The method of claim 143 wherein the image is included in a series of images; and further comprising concatenating the series of images to create a video.
 145. The method of claim 142 wherein the data relating to the condition in the environment includes a plurality of images; and further comprising comparing the plurality of images to determine a proximate variance of an object among the plurality of images.
 146. The method of claim 145 further comprising analyzing the proximate variance to determine movement of the object.
 147. The method of claim 146 further comprising analyzing the movement of the object to determine velocity of the movement.
 148. The method of claim 142 wherein the light source in each of the nodes is included in an array to be selectively enabled and disabled by the controller, wherein the array includes a plurality of light sources, wherein each light source included in the plurality of light sources emits at least one wavelength respective to each light source; and further comprising selectively operating the plurality of light sources.
 149. The method of claim 148 wherein the sensor in each of the nodes is included in the array to be selectively enabled and disabled by the controller; wherein the array includes a plurality of sensors; wherein each sensor included in the plurality of sensors is sensitive to at least one wavelength respective to the each sensor; and further comprising selectively operating the plurality of sensors.
 150. The method of claim 149 wherein the light source and the sensor are included as a light emitting semiconductor device; and further comprising selectively operating the light emitting semiconductor device between a sensing operation and an emitting operation, the sensing operation being defined by the light emitting semiconductor device sensing the environmental light, and the emitting operation being defined by the light emitting semiconductor device emitting the illuminating light.
 151. The method of claim 150 wherein the array includes a plurality of light emitting semiconductor devices.
 152. The method of claim 148 wherein at least a portion of the plurality of light sources included in the array are selected from a group consisting of monochromatic light emitting diodes (LED), white light emitting diodes (LED), and infrared light (IR) emitting diodes (LED).
 153. The method of claim 142 further comprising: designating at least a part of the illuminating light as a marker light; emitting the illuminating light including the marker light to the environment; sensing environmental light that is reflected and that includes the marker light; calculating a delay between emitting the marker light and sensing the marker light; and analyzing the delay to determine a distance between the array and the point of reflection.
 154. The method of claim 153 further comprising: analyzing the delay using a node in the network of nodes; determining the distance between the node and the point of reflection; intercommunicating the distance within the network by transmitting and receiving the data light; analyzing the distance calculated by at least a portion of the nodes in the network of nodes to determine the condition in the environment.
 155. The method of claim 154 further comprising analyzing the distance calculated by at least a portion of the nodes in the network to determine a multidimensional arrangement of the condition in the environment.
 156. The method of claim 142 wherein the dominant wavelength is indicative of a substance present in the environment.
 157. The method of claim 142 wherein the light source and the sensor are included as a light emitting semiconductor device; and further comprising selectively operating the light emitting semiconductor device between a sensing operation and an emitting operation, the sensing operation being defined by the light emitting semiconductor device sensing the environmental light, and the emitting operation being defined by the light emitting semiconductor device emitting the illuminating light; and further comprising using a switching circuit to alternate the light emitting semiconductor device between the sensing operation and the emitting operation.
 158. The method of claim 157 further comprising emitting the illuminating light and receiving the environmental light substantially simultaneously from the light emitting semiconductor device; wherein the light emitting semiconductor device includes a light emitting diode to emit the illuminating light and a photodiode to sense the environmental light, the light emitting diode being operable as the photodiode.
 159. The method of claim 158 further comprising analyzing the environmental light by measuring a drive voltage of the light emitting semiconductor device, determining a difference between a measured voltage across the light emitting semiconductor device and the drive voltage, and performing time-domain matching of the measured voltage and the environmental light using cross-correlation.
 160. The method of claim 142 wherein at least a portion of the nodes in the network perform analysis using distributed computing.
 161. The method of claim 142 further comprising intercommunicating among the nodes by transmitting and receiving an electromagnetic signal; and synchronizing at least a portion of the nodes in the network by including a synchronization signal in the electromagnetic signal.
 162. The method of claim 142 further comprising selectively including a biological affective wavelength in at least a part of the illuminating light to affect an object in the environment.
 163. The method of claim 142 wherein the data light is defined by a plurality of data wavelengths; wherein the data is transmittable at the plurality of data wavelengths; and wherein a quantity of data wavelengths included in the data light correlates with a bandwidth at which the data is transmittable.
 164. The method of claim 142 wherein the data light includes at least one addressing bit to address the nodes intended to receive the data.
 165. The method of claim 142 wherein the data included in the data light includes at least one error detection bit.
 166. The method of claim 142 further comprising storing feedback regarding an analysis in a memory; and intercommunicating the feedback from the analysis within the network.
 167. The method of claim 166 further comprising analyzing the feedback using machine learning.
 168. The method of claim 166 further comprising analyzing the feedback using a neural network.
 169. The method of claim 142 further comprising storing feedback regarding a prior analysis performed by the controller in a memory; and analyzing the feedback regarding the prior analysis to perform a subsequent analysis.
 170. The method of claim 169 wherein the subsequent analysis is performed using machine learning.
 171. The method of claim 142 wherein a wavelength conversion material is positioned between the array and the environment; further comprising absorbing at least part of a source light and emitting a converted light having a converted wavelength range, the source light being received and absorbed by the wavelength conversion material, and the converted light being emitted by the wavelength conversion material.
 172. The method of claim 171 wherein the wavelength conversion material is selected from a group consisting of a fluorescent material, a luminescent material, and a phosphorescent material.
 173. The method of claim 171 further comprising receiving the illuminating light by the wavelength conversion material as the source light; converting the source light to the converted light; and emitting the converted light the converted wavelength range.
 174. The method of claim 171 further comprising receiving the environmental light by the wavelength conversion material as the source light; converting the source light to the converted light; and receiving the converted light by the sensor within the converted wavelength range.
 175. The method of claim 171 wherein the converted wavelength range includes shorter wavelengths than the source wavelength range; and wherein the wavelength conversion material converts the source light to the converted light by performing an anti-Stokes shift.
 176. The method of claim 171 wherein the converted wavelength range includes longer wavelengths than the source wavelength range; and wherein the wavelength conversion material converts the source light to the converted light by performing a Stokes shift.
 177. The method of claim 142 wherein the converted wavelength range of the converted light includes a variable dominant wavelength respective to the condition in the environment; wherein the dominant wavelength is indicative of a substance in the environment; and wherein the controller correlates the dominant wavelength with the substance.
 178. The method of claim 177 wherein the substance is selected from a group consisting of an object, element, compound, particulate, and biological agent.
 179. The method of claim 142 wherein the controller is operatively connected to a voltage sensor to sense an open circuit voltage across the sensor.
 180. The method of claim 142 further comprising transmitting the data using an operation selected from a group consisting of pulse width modulation (PWM), pulse amplitude modulation (PAM), intensity modulation, color sequencing, and duty cycle variation.
 181. The method of claim 142 further comprising dynamically adjusting a sample rate at which the data is transmitted; and wherein the sample rate correlates with a resolution sensed by the array.
 182. The method of claim 142 further comprising including data in the data light digitally.
 183. The method of claim 142 further comprising encrypting the data included in the data light.
 184. The method of claim 142 wherein the lighting system further comprises a power supply to drive the array.
 185. The method of claim 142 further comprising operating the light source in a pulsed mode.
 186. The method of claim 142 further comprising processing the environmental light to remove noise.
 187. The method of claim 142 further including characterizing characterizes luminosity of the environmental light using the controller.
 188. The method of claim 142 wherein at least a portion of the nodes in the network of nodes includes a piezoelectric substrate. 